Method for rapidly determining effective sterilization , deimmunization, and/or disinfection

ABSTRACT

A method for rapidly determining effective sterilization, deimmunization, and/or disinfection of equipment and/or supplies by a device. The method includes providing a defined surrogate protein having a predetermined sequence representative of an infectious agent potentially contaminating the equipment and/or the supplies to be sterilized, deimmunized, and/or disinfected by the device. The defined surrogate protein having the predetermined sequence is subjected to sterilization, deimmunization, or disinfection. The effectiveness of the sterilization deimmunization, or disinfection is rapidly determined by determining if the defined surrogate protein has been destroyed.

RELATED APPLICATIONS

This application claims benefit of and priority to U.S. Provisional Application Ser. No. 62/314,617 filed Mar. 29, 2016, under 35 U.S.C. §§119, 120, 363, 365, and 37 C.F.R. §1.55 and §1.78, which is incorporated herein by this reference.

FIELD OF THE INVENTION

This invention relates to a method for rapidly determining effective sterilization, deimmunization, and/or disinfection.

BACKGROUND OF THE INVENTION

A wide range of infectious agents, including infectious proteins, spore forming bacteria, vegetative bacteria, fungus and viruses have major impacts in medical settings. The process to remove infectious organisms or render them non-infectious from medical equipment makes use of a wide range of sterilization devices or equipment and disinfection devices and processes. The CDC lists examples of infectious agents and microorganisms by resistance to standard disinfection and sterilization processes. See Table 1 below from CDC's Guideline for Disinfection and Sterilization in Healthcare Facilities, 2008.

Some infectious agents, such as the HIV virus, may be easy to remove from medical equipment. Many infectious agents, including vegetative bacteria, are moderately difficult to eliminate. Other infectious agents, such as prions, can only be destroyed by extremely harsh conditions that damage and/or destroy modern medical equipment. Failure to eliminate infectious agents from medical equipment before use can put patients at extreme risk of injury and death.

TABLE 1 Decreasing order of resistance of infectious agents and microorganisms to disinfection and sterilization. Agent Category Example Organisms or Diseases Prions Creutfeldt-Jakob Disease Bacterial spores Bacillius atrophaeus Coccidica Cryptosporidium Mycobacteria M. tuberculosis, M. terrae Nonlipid or small viruses polio, coxsackie Fungi Aspergillus, Candida Vegetative bacteria S. aureus, P. aeruginosa Lipid of medium-sized viruses HIV, herpes, hepatitis B

Some conventional methods to determine if sterilization equipment functions effectively may rely on FDA approved Biologic Indicator process (BI strips) in a multi-step process. This widely accepted conventional process starts with filter papers infused with a defined number of bacterial spores (BI strips). The BI strips are subjected to a standard cycle by the sterilization equipment or device, e.g., an ethylene oxide (EtO) sterilization, radiation, or steam sterilization equipment which is being qualified. After the sterilization process is completed, the treated strips are then placed in a defined bacterial media for growth; frequently for days to weeks. If no growth is seen after the defined period, the sterilization process by the medical equipment being certified is declared a success. Together this combination of supplies and techniques is the approved process to qualify sterilization equipment in positive or negative process. If there is growth, the sterilization equipment fails and if there is no growth the sterilization equipment passes.

The conventional biologic indicator tests may use one of three different species of bacteria. The standard species used to test the effectiveness of ethylene oxide (EtO) sterilization is B. atrophaeus. To test the effectiveness of gamma radiation sterilization, the bacteria species used is B. pumilis. To test the effectiveness of steam sterilization the bacteria species used is G. stearothermophilus. However, the three species that are used to qualify sterilization capacity of equipment are not bacteria that commonly cause disease in humans. Instead, the species are surrogate species, strains of soil bacteria that form high persistent spores. They are used instead of medically relevant infectious agents, because, inter alia, the spores of the bacteria are extremely difficult to damage such that they can no longer replicate, and if for some reason a health care worker or patient accidently comes in contact with the spores through use or on improperly cleaned equipment, there is very little chance that the human will become ill. As spores from the surrogate species are scientifically known to be more difficult to destroy than medically relevant species, such as Polio or S. aureus, e.g., Methicillin-resistant Staphylococcus aureaus (MRSA), when the sterilization equipment is qualified to destroy all spores on a BI test strip, the FDA accepts that the equipment is also able to destroy all organisms that rank lower for resistance to sterilization.

The conventional methods discussed above used to qualify effective sterilization, deimmunization, or disinfection may only measure the ability of the surrogate organisms to grow after sterilization treatment. However, such conventional methods do not indicate how the surrogate organisms are damaged and/or destroyed resulting in the absence of growth. Conventional surrogate testing methods also require the accurate production, storage, transport and handling of 10 thousand to 100 million pure bacteria spores, proper control of growth medias, extended period of growth of the specific spores and careful protection of all growth materials for environmental contamination to qualify if all the test surrogate organisms were completely eliminated. If any component of the process is not vigorously controlled, the sterilization qualification could give false positive or false negative results. False positive results will trigger extensive effort to unnecessarily repair sterilization equipment as well as the recall of days or weeks of sterilized medical equipment and the patients treated with such equipment. False negative results are worse because they will result in defective sterilization equipment being used and the resulting contaminated medical equipment endangering patients.

For other infectious organisms, such as members of the bacterial genera Clostridium, Staphylococcus or fungal genera Trichophyton or Candida, and the like, specific tests for each genera may be based on similar fundamentals. See Table 2 below for a list of common bacteria and fungus genera and species having an impact on human medicine.

TABLE 2 Common bacteria and fungus genera and species having an impact on human medicine. Health Care Application - Problem pathogen or BL1/sterilization Genus Example Species testing organism. Bacillus Bacillus subtilis Research organism, used as an “indicator organism” during disinfection testing. BL1. Bacillus atrophaeus Used as an “indicator organism” during gas (EtO) sterilization procedure. BL1. Bacillus pumilis Used as an “indicator organism“ during radiation sterilization procedure. BL1. Geobacillus stearothermophilus Used as an “indicator organism” (formerly B. stearothermophilus) during steam sterilization procedure. BL1. Bacillus anthracis Causes anthrax. Bacillus cereus Causes food poisoning similar to that caused by Staphylococcus. Clostridium Clostridium sporogenes Used as a surrogate for C. botulinum when testing the efficacy of commercial sterilization. Clostridium tetani Causes tetanus. Clostridium botulinum Causes botulism poisoning. Clostridium perfringens Causes gas gangrene Clostridium difficile Causes C. dif GI infection. Clostridium novyi Causes a wide range of human and animal infections depending on type. Mycobacterium Mycobacterium tuberculosis Major cause of human tuberculosis. Mycobacterium africanum Slow growing form of tuberculosis. Mycobacterium caprae More rare form of human tuberculosis. Mycobacterium kansasii Chronic human pulmonary disease resembling tuberculosis (involvement of the upper lobe). Mycobacterium ulcerans Infects the skin and subcutaneous tissues, giving rise to indolent nonulcerated and ulcerated lesions. Mycobacterium interjectum Chronic lymphadenitis Mycobacterium leprae Causes leprosy Mycobacterium lepromatosis Causes leprosy Mycobacterium terrae Causes serious skin infections that are relatively resistant to antibiotic therapy. Used to study effectiveness of disinfection processes for reusable medical instruments. Mycobacterium gastri Casual resident of human stomachs, but not considered an etiologic agent of disease. (BL1). Staphylococcus Staphylococcus aureus Causes a variety of infections in the body, including boils, cellulitis, abscesses, wound infections, toxic shock syndrome, pneumonia, and food poisoning. Substrain - Methicillin-resistant Staphylococcus aureus (MRSA). Substrain - Vancomycin-resistant Staphylococcus aureus (VRSA) - acquired gene from VRE. Staphylococcus capitis Associated with prosthetic valve endocarditis, forms biofilms. Staphylococcus epidermidis Hospital-acquired concern as it forms biofilms catheters or other surgical implants. Staphylococcus haemolyticus Second-most frequently isolated hospital-acquired Infection, often associated with the insertion of medical devices; highly antibiotic- resistant phenotype and able to form biofilms. Staphylococcus lugdunensis Wide variety of infections including cardiovascular infections, osteomyelitis and prosthetic/native joints infections, skin and soft-tissue infection, central nervous infections, peritonitis, endocephalitis, and urinary tract infections. Staphylococcus saccharolyticus May cause of infective endocarditis. Staphylococcus saprophyticus Common cause of community- acquired urinary tract infections. Staphylococcus auricularis Occasionally can be involved with human skin infections. Salmonella Salmonella enterica Causes food poisoning. Enterococcus Enterococcus faecalis Can cause endocarditis and septicemia, urinary tract infections, meningitis, and other infections. Substrain - Vancomycin-resistant Enterococcus (VRE). Enterococcus faecium Neonatal meningitis or endocarditis. Substrain - Vancomycin-resistant Enterococcus (VRE). Enterococcus gallinarum Known to cause outbreaks and spread in hospitals. Enterococcus hirae Endocarditis and septicemia in humans. Enterococcus malodoratus Frequently the cause of hospital- acquired noscomial infections, bloodstream infections, and urinary tract infections. Escherichia Escherichia coli Some serotypes can cause serious food poisoning in their hosts. Substrain K-12 strain commonly used in recombinant DNA work (BL1). Substrain O157:H7 causes serious illness or death in the elderly, the very young, or the immunocompromised. Substrain O104:H4, can trigger major cause of foodborne illness and lead to hemolytic-uremic syndrome (HUS). Escherichia fergusonii Known to infect open wounds and may also cause bacteraemia or urinary tract infections; highly resistant to the antibiotic ampicillin and some also resistant to gentamicin and chloramphenicol. Helicobacter Helicobacter pylori Cause gastritis and ulcers. Helicobacter hepaticus May be associated with Crohn's disease and ulcerative colitis. Helicobacter bilis May be associated with Crohn's disease and ulcerative colitis. Helicobacter ganmani May be associated with Crohn's disease and ulcerative colitis. Klebsiella Klebsiella pneumoniae Causes pneumonia, urinary tract infections, septicemia, meningitis, diarrhea, and soft tissue infections; naturally resistant to many antibiotics. Substrain - CREs - carbapenem- resistant Klebsiella pneumoniae (CRKP). Klebsiella oxytoca Cause colitis and sepsis. Neisseria Neisseria gonorrhoeae Causes Gonorrhea. Neisseria meningitidis Causes meningitis. Pseudomonas Pseudomonas aeruginosa A multidrug resistant pathogen associated with hospital-acquired infections such as ventilator- associated pneumonia and various sepsis syndromes. Common in CF patients. Pseudomonas mendocina Occasionally causes hospital- acquired infections, such as infective endocarditis and spondylodiscitis. Pseudomonas fluorescens Produces enzymes that cause milk to spoil and occasionally infects immunocompromised patients. Pseudomonas putida Used in bioremediation, or the use of microorganisms to biodegrade oil. Trichophyton Trichophyton rubrum Most common cause of athlete's (Fungus) foot, fungal infection of nail, jock itch, and ringworm. Trichophyton tonsurans Causes ringworm infection of the scalp. Trichophyton interdigitale One of three common fungi which cause ringworm. Trichophyton mentagrophytes Causes tinea infections including athlete's foot, ringworm, jock itch, and similar infections of the nail, beard, skin and scalp. Trichophyton concentricum Associated with the skin infection tinea imbricate. Candida Candida albicans Dimorphic fungus that grows both (Fungus) as yeast and filamentous cells; Responsible for 50-90% of all cases of candidiasis in human. Important causes of morbidity and mortality in immunocompromised patients. Biofilms may form on the surface of implantable medical devices. Cause of 85-95% of vaginal infections cases are responsible for physician office visits every year. Candida dubliniensis A fungal opportunistic pathogen originally isolated from AIDS patients. It is also occasionally isolated from immunocompetent individuals. Candida tropicalis Common pathogen in neutropaenic hosts; research suggests that C. tropicalis, working synergistically with Escherichia coli and Serratia marcescens. May cause or contribute to Crohn's disease Candida auris Causes candidiasis in humans; often acquired in the hospital when human immune systems are weakened; causes fungemia, yielding candidemia (systemic candidiasis); attracted clinical attention because of multidrug resistance.

Examples of standardized methods for sterilization or disinfection (A) and standardized testing methods protocols (B) used to determine the effectiveness of sterilization or disinfection, as shown in Table 3 below:

TABLE 3 Approved Methods of Sterilization or Disinfection and Qualifying Test Protocols (A) Standard Methods for Preparing Healthcare Equipment Disinfection Sterilization Alcohol Steam Sterilization Chlorine and Chlorine Compounds Flash Sterilization Formaldehyde Ethylene Oxide “Gas” Sterilization Glutaraldehyde Hydrogen Peroxide Gas Plasma Hydrogen Peroxide Peracetic Acid Sterilization Iodophors Ionizing Radiation Ortho-phthalaldehyde Dry-Heat Sterilizers Peracetic Acid Liquid Chemicals Peracetic Acid and Hydrogen Performic Acid Peroxide Filtration Phenolics Microwave Quaternary Ammonium Compounds Glass Bead “Sterilizer” Radiation Vaporized Hydrogen Peroxide Pasteurization Ozone Flushing- and Washer-Disinfectors Formaldehyde Gaseous Chlorine Dioxide Vaporized Peracetic Acid Infrared radiation (B) Standard Test to Qualtify Healthcare Equipment Test Name Example Test Species BI (ethylene oxide (EtO) sterilization) B. atrophaeus BI (gamma radiation sterilization) B. pumilis BI (steam sterilization) G. stearothermophilus AOAC Sporicidal Efficacy Test Method Clostridium sporogenes Bacillus subtilis AOAC Tuberculosis Rate of Kill Mycobacterium terrae AOAC Use Dilution Test Pseudomonas aeruginosa Staphylococcus aureus Salmonella enterica AOAC Fungicidal Efficacy Test Method Trichophyton mentagrophytes

For each standard test protocol, a define number of organisms are placed on a carrier, such as tube, filter paper, or coated on and in a test solid surface. The specific organisms may be a particular infectious species or could be a surrogate species of the same genus that is closely related to the infectious species. In all cases, the species, carrier and growth conditions are defined by the FDA and/or the Association of Analytical Communities (AOAC) protocol. Following treatment with sterilization or disinfection equipment, the carrier with the specific species sample is placed into ideal growing conditions for the particular test species. After a required period in culture, usually 2 to 30 days, the culture is monitored. If no growth is observed, the sterilization or disinfection equipment is declared to be operating within required parameters.

In addition to enabling growth and infectivity, protein components of infectious organisms could trigger severe immunogenic or allergic reactions in susceptible individuals even at very low level. Examples include mold proteins that are able to trigger severe allergic reactions even if the mold has been rendered no longer able to grow. Immunogenic proteins can also occur in food such as gliadin, a highly immunogenic protein component of the seed storage protein gluten in wheat and related grains. Gliadin can trigger reactions in most individuals suffering from Crohn's disease. It is critical that immunogenic proteins are completely removed from any equipment that will be used in conjunction with susceptible individuals.

A wide range of pathogenic organisms use a multicopper oxidase with 3 cupredoxin superfamily domains for growth and survival. As disclosed herein, the loci suf I that contains a critical protein that confers different functions depending on the genus (bacteria or fungus) and this critical protein can be targeted. Depending on the genus, the suf I loci encoded protein can have different names. The functions of the protein encoded by suf I include cell division (FtsP), formation of spore coat proteins (CotA), chromosome partitioning, inorganic ion transport, and metabolism and cell wall, membrane, and envelope formation. As the protein product of the suf I loci are absolutely critical for the survival of the spores (in spore forming bacteria) and/or growth (all bacteria and fungus), if the protein product of the suf I loci is irreversibly fragmented into short polypeptides and amino acids, the bacteria or fungus cannot survive. Additionally, it is likely that a sterilization method that clearly demonstrates fragmentation of the protein product of the sufi I loci would also fragment other proteins in the bacterium or fungus. Bacteria and fungus can be divided into distinct genus each containing multiple species. Many species also have subspecies that carry unique characteristics include multi-drug resistance. In human health situations, certain bacteria and fungus species and subspecies are of major concern because they are capable of causing disease. Related species may be used in medical research, e.g., E. coli K12, or as indicator species for qualification of sterilization, e.g., B. atrophaeus used to qualify gas sterilization. See Table 2 above for a list of common bacteria and fungus genera and species with impact on human medicine.

Prions are a unique category of a transmissible infectious agent that comprised only of protein, without DNA or RNA. Prions can cause a wide range of neurodegenerative diseases known as transmissible spongiform encephalopathies (TSE) or prion diseases including the new variant Creutzfeldt-Jakob disease (nvCJD). See Table 4 below. Infectious prions are in fact an abnormally folded brain protein. This brain protein (Protease resistant Proteins, PrP) can be folded into two different structural (tertiary) forms, the normal brain protein, PrP_(c), and the abnormal, disease triggering form, PrP_(sc). The disease triggering form, PrP_(sc), is found in high quantity in the brain of infected humans and animals and can be transferred to a new host with the transfer of infected material. Once in the new host, the abnormally folded protein (PrP_(sc)) causes disease symptoms by promoting the unfolding of the normal host protein (PrP_(c)) and refolding into the disease causing form (PrP_(sc)). PrP proteins can also be partially cleave and still retain their infectious characteristics. Full length mature PrP protein (both PrP_(c) and PrP_(sc)) is 209 amino acids long. Limited proteolysis of PrP_(sc) will cleave amino acids from the amino terminus resulting in another infectious protein form PrP 27-30 that is approximately 142 amino acids long. Additional cleavage that significantly reduces the 142 amino acid long PrP 27-30 is needed to render the PrP protein irreversibly non-infectious. Although most infectious agents can be permanently rendered non-infectious by heat or steam, these methods are not sufficient to eliminate infectious prions from medical equipment.

TABLE 4 Example of Prion Diseases in Different Species and Potential Origin of the Infectious Protein. Disease Species Potential Origin Disease Species Potential Origin Creutzfeldt-Jakob Human Inherited Scrapie Sheep and Inherited/ disease (CJD) Goat environmental New Variant Human Consumption, Bovine Spongiform Cattle Consumption Creutzfeldt-Jakob Medical Encephalopathy disease (CJD) Contamination (BSE) Fatal Familial Human Inherited Transmissible Mink Mink Environmental Insomnia (FFI) Encephalopathy (TME) Gerstmann-Straussler Human Inherited Chronic Wasting Mule Deer Environmental disease (GSD) Disease (CWD) and Elk Huntington disease- Human Inherited Feline Spongiform Cats Consumption like type 1 (HDL1) Encephalopathy (FSE) Kuru Human Consumption of Exotic Ungulate Nyala and Environmental Human Brains Encephalopathy Greater (EUE) Kudu

As discussed above, prions are abnormally folded protease resistant proteins (PrP_(sc)) that cause disease symptoms by promoting the unfolding of normal proteins (PrP_(c)) and refolding into the disease causing protein form (PrP_(sc)). As the level of the PrP_(sc) rises in the patient's brain, symptoms of progressive dementia, myoclonic seizures, abnormalities of high cortical function, cerebellar and corticospinal disturbances develop. The period between infection and development of disease can extend for years to decades. The duration of disease symptoms is variable but is typically 8 to 18 months.

Once prion proteins fold into the infectious form (PrP_(sc)), they are extremely difficult to render non-infectious. Conventional methods to sterilize medical equipment contaminated with prions, such as high heat to promote loss of function of other protein types by triggering loss of tertiary structure, are ineffective because unlike most proteins, the denatured prion proteins, both infectious and non-infectious, will spontaneously refold by themselves back to their pre-treatment forms. In some cases, conventional methods may actually result in refolded into infectious form promoting the conversion of the non-infection prion protein into the infectious prion protein.

To render infectious proteins such as prions irreversibly non-infectious, all infectious proteins must be fragmented into small polypeptides, amino acids or components. The only currently approved conventional method for this process is harsh treatment of medical equipment and supplies with caustic soda, an extremely harsh process that frequently damages and/or destroys medical equipment.

Determining whether or not an infectious prion (PrP_(sc)) sample has been permanently destroyed can be extremely difficult and time consuming. Conventional methods for determining whether an infectious prion has been permanently destroyed require that after attempted deactivation, the PrP_(sc) sample is injected into a matched susceptible animal that is then followed for an extended time to see if the animal develops disease. In larger animals, the process can take years, but even in a small animal such as a mouse, the test can take months. As there is a potential for inter-animal variation and poor test accuracy, a large animal test pool is required to obtain relatively accurate results.

Immunogens may include a wide range of molecules including proteins that can trigger dramatic immunologic responses in susceptible individuals. The responses can trigger serious allergic reactions on the skin (e.g., poison ivy rash), in the gut (e.g., triggering a flare-up in Crohn's disease), in the lung (e.g., asthma) or a systemic response (e.g., anaphylaxis). Protein immunogens are a special class of immunogens produced by a wide range of bacteria, fungus (e.g. mold) or plants and can be difficult to destroy. An example of a common plant immunogen is gluten. Common grains such as various strains of wheat, farro, rye and spelt are derived from wild and domesticated grains of the Triticum, Aegilops and Secale genera. Common to all these species is the seed storage protein complex called gluten. When seeds are ground into flour, the gluten protein complex gives bread dough its elastic quality and bread its spongy texture. Unfortunately gluten is comprised of several proteins including Gliadin (also called Prolamin) which triggers severe T cell attack on the gut of patients with the autoimmune disease Celiac disease (CD). Gliadins can be typed as α, γ, and ω with a small protease resistant fragment (p57-73) of α-gliadins triggering the most severe destructive T cell response. As a results CD patients must not only avoid products containing gluten, but also need to be extremely careful to avoid small amounts of residual α-gliadin that may contaminate food preparation utensils.

Protease resistant proteins like α-gliadin are resistant to destruction so it is critical that devices and methods used to destroy them and other immunogens (also called allergens) can be easily checked to ensure they are operating at peak efficiency. If not, residual allergens can trigger life threatening responses in sensitive patients. The process of removing immunogens by deimmunization methods or devices is called deimmunization. The ability to test for the destruction of different immunogens on surfaces is not standardized. Usually affected patients are subjected to skin test regiments to determine their individual reactions to different candidate immunogens/allergens. The patient is then advised to avoid all immunogen contact and discard any materials potential contaminated with the specific immunogen or allergen. In cooking and manufacturing situations, extreme care must be taken to avoid potential cross contamination to the point that food packaging labels frequently carry warning labels about the potential issues.

Thus, a method is needed to determine irreversible destruction of proteins critical for the growth of infectious organisms, immunogenic proteins, and/or infectious proteins (e.g., prions) and thus rapidly and accurately determines the effectiveness of sterilization, deimmunization, and/or disinfection of equipment or supplies by a device. With such a method for rapidly determining effective sterilization, deimmunization, and/or disinfection, medical personnel and patients can have confidence that the medical equipment used for patient treatment is not contaminated with potentially lethal or immunogenic proteins. Without such a method, medical personnel may believe they are using properly sterilized equipment and then later discover that they have accidentally exposed their patients to lethal infections and harmful immune reactions

SUMMARY OF THE INVENTION

In one aspect, a method for rapidly determining effective sterilization, deimmunization, and/or disinfection of equipment and/or supplies by a device is featured. The method includes providing a defined surrogate protein having a predetermined sequence representative of an infectious agent potentially contaminating the equipment and/or the supplies to be sterilized, deimmunized, and/or disinfected by the device. The defined surrogate protein having the predetermined sequence is subjected to sterilization, deimmunization, or disinfection. The effectiveness of the sterilization, deimmunization, or disinfection is rapidly determined by determining if the defined surrogate protein having the predetermined sequence has been destroyed.

In one embodiment, the defined surrogate protein may include proteins critical for stability, growth and/or infectious capacity of infectious agents. The defined surrogate protein may include a protein critical for stability, growth and/or infectious capacity of surrogate organisms of infectious agents. The infectious agent may include one or more of: an infectious protein, an infectious spore forming bacteria, an infectious vegetative bacteria, an infectious fungus, and an infectious virus. The defined surrogate protein may include pathogenic proteins, proteins critical for the growth of infectious agents, and immunogenic proteins. The predetermined sequence may be defined by the sequence:

(SEQ ID NO: 1)         10          20          30          40          50 MYNYTSAKYE  VPIAIQDRSF  NEDGSLNFPS  EGDNPTIHPY  WQPEFFGDTI MVNGRVWPNM  NVDMTRYRFR  LLNGSNARFY  NLKFSNGMQF  WQIGTDGGYL NKPVPLTSLL  ISPGERADIL  VDFTEIPAGT  RIILNNDANA  PYPTGDAPDK DTTGQIMQFT  VQHNDHHHHH  H

The defined surrogate protein for SEQ ID NO: 1 may be at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence. The predetermined sequence may be defined by the sequence:

(SEQ ID NO: 2)         10          20          30          40          50 MTLEKTYYEV  TMEECTHQLH  RDLPPTRLWG  YNGLFPGPTI  EVKRNENVYV KWMNNLPSTH  FLPIDHTIHH  SDSQHEEPEV  KTVVHLHGGV  TPDDSDGYPE AWFSKDFEQT  GPYFKREVYH  YPNQQRGAIL  WYHDHAMALT  RLNVYAGLVG AYIIHDPKEK  RLKHHHHHH

The defined surrogate protein for SEQ ID NO: 2 may be at least 95% homologous to the predetermined sequence or substantial fragment of the predetermined sequence. The predetermined sequence may be defined by the sequence:

(SEQ ID NO: 3)         10          20          30          40          50 MTGMPEGEGV  DSNLLGGDGG  DIAYPYYLIN  GRIPVAATSF  KAKPGQRIRI RIINSAADTA  FRIALAGHSM  TVTHTDGYPV  IPTEVDALLI  GMAERYDVMV TAAGGVFPLV  ALAEGKNALA  RALLSTGAGS  PPDHHHHHH

The defined surrogate protein for SEQ ID NO: 3 may be at least 95% homologous to the predetermined sequence or substantial fragment of the predetermined sequence.

The predetermined sequence may be defined by the sequence:

(SEQ ID NO: 4)         10          20          30          40          50 MTGYKNYTLK  AQKGKTEFYK  NNFSNTLGYN  GNLLGPTLKL  KKGDKVKIKL INNLDENTTF  HWHGLEVNGK  VDGGPSQVIK  PGKEKTIKFE  VNQDSATLWY HPHPSPNTAK  QVYNGLSGLL  YIEDSKKNHH  HHHH

The defined surrogate protein SEQ ID NO: 4 may be at least 95% homologous to the predetermined sequence or substantial fragment of the predetermined sequence.

The predetermined sequence may be defined by the sequence:

(SEQ ID NO: 5)         10          20          30          40          50 MTGFRHEKVL  CLKTWHVDEQ  GAFTPFSVPR  QAAREGTRGR  YSTINGKHVP TIDLPAGQIV  RVRLLNVDNT  VTYRLNPNGE  ARIYANDGHP  VEPRGFEGQY WIGPGMRLEL  ALKVPEAGTE  LSLRDGPVRL  ATIRSVAHHH  HHH

The defined surrogate protein SEQ ID NO: 5 may be at least 95% homologous to the predetermined sequence or substantial fragment of the predetermined sequence. The predetermined sequence may be defined by the sequence:

(SEQ ID NO: 6)         10          20          30          40          50 MTITLEWSVT  TGYRRLDGVK  KRVYLINGLF  PGPTIEARSG  DSLQVQVTNN IQDEGLVIHW  HGLHMRGANH  MDGVTGVTQC  PIVPGDSMLY  NFTISQSQSG TFWYHAHSAL  QRAEGLYGGF  VVHKPSTHHH  HHH

The defined surrogate protein SEQ ID NO: 6 may be at least 95% homologous to the predetermined sequence or substantial fragment of the predetermined sequence. The predetermined sequence may be defined by the sequence:

(SEQ ID NO: 7)         10          20          30          40          50 MTAETHTWYF  KTSWVDANPD  GVFPRKMIGF  NDSWPLPTLR  VKKGDTVNLY LINGFDDRNT  SLHFHGLFQH  GTNQMDGPEM  VTQCPIPPGE  TFLYNFTVDD QVGSYWYHSH  TSGQYGDGMR  GVFIIEDHHH  HHH

The defined surrogate protein SEQ ID NO: 7 may be at least 95% homologous to the predetermined sequence or substantial fragment of the predetermined sequence. The predetermined sequence may be defined by the sequence:

(SEQ ID NO: 8)         10          20          30          40          50 MKTVRVPVPQ  PQPQNPSQPQ  PQRQVPLVQQ  QQFPGQQQQP  PPQQPYPQPQ PFPSQQPYLQ  LQPFPQPQPF  PPQLPYHHHH  HH

The defined surrogate protein SEQ ID NO: 8 may be at least 95% homologous to the predetermined sequence or substantial fragment of the predetermined sequence. The rapidly determining may include a sensitive protein analysis procedure. The sensitive protein analysis procedure may include one or more of: a Western Blot analysis, a protein assay analysis, a magnetic separation analysis, a peptide analysis, a mass spectrometry analysis, and a gas chromatography analysis. The sensitive protein analysis procedure may include fluorescence analysis of proteins covalently crosslinked on a solid surface. The sensitive protein analysis procedure may include fluorescence analysis of proteins covalently crosslinked on magnetic beads. The defined surrogate protein having the predetermined sequence may be disposed on a surface, disposed on a test strip, disposed in or on a vessel, on a tube, or in or on a holder. The holder may be disposed to receive a flow of a sterilization agent, a deimmunization agent or a disinfection agent.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Other objects, features and advantages will occur to those skilled in the art from the following description of a preferred embodiment and the accompanying drawings, in which:

FIG. 1 is a schematic block diagram showing the primary steps of one embodiment of the method for rapidly determining effective sterilization, deimmunization, and/or disinfection of this invention;

FIG. 2 is a schematic diagram showing examples of multi-well glass slides having samples of one or more of the defined surrogate protein having a predetermined sequence in wells which are subjected to sterilization, deimmunization, or disinfection to provide a visual depiction of the effectiveness of sterilization, deimmunization, and/or disinfection;

FIG. 3 is a schematic block diagram showing one example of the multi-well glass slides shown in FIG. 2 placed in a holder disposed at the end of a flow of sterilization, deimmunization, or disinfection agent in accordance with one embodiment of this invention;

FIG. 4 shows an example of an amino acid comparison of human PrP proteins with a selection of other species of PrP proteins;

FIG. 5 shows an example of a Western gel where the recombinant protein runs approximately 28 kDa inside;

FIG. 6 shows an example of a Western Blot where the absence of bands indicates successful sterilization, deimmunization, or disinfection;

FIG. 7 is a homology diagram comparing protein sequences of a research Clostridium species and two pathogenic Clostridium species;

FIG. 8 shows an example of a Western Blot for a defined Clostridium surrogate protein having a predetermined sequence that has been subjected to sterilization, deimmunization, or disinfection;

FIG. 9 is a homology diagram comparing protein sequences of a three research Bacillus species;

FIG. 10 shows an example of a Western Blot for a defined Bacillus surrogate protein having a predetermined sequence that has been subjected to sterilization, deimmunization, or disinfection;

FIG. 11 is a homology diagram comparing protein sequences of three pathogenic Mycobacterium species;

FIG. 12 shows an example of a Western Blot for a defined Mycobacterium surrogate protein having a predetermined sequence that has been subjected to sterilization, deimmunization, or disinfection;

FIG. 13 is a homology diagram comparing protein sequences of three pathogenic Staphylococcus species;

FIG. 14 shows an example of a Western Blot for a defined Staphylococcus surrogate protein having a predetermined sequence that has been subjected to sterilization, deimmunization, or disinfection;

FIG. 15 is a homology diagram comparing protein sequences of a research Pseudomonas species and two pathogenic Pseudomonas species;

FIG. 16 shows an example of a Western Blot for a defined Pseudomonas surrogate protein having a predetermined sequence that has been subjected to sterilization, deimmunization, or disinfection;

FIG. 17 is a homology comparing protein sequences of two pathogenic Trichophyton species;

FIG. 18 shows an example of a Western Blot for a defined Trichophyton surrogate protein having a predetermined sequence that has been subjected to sterilization, deimmunization, or disinfection;

FIG. 19 is a homology comparing protein sequences of four pathogenic Candida species;

FIG. 20 shows an example of a Western Blot for a defined Candida surrogate protein having a predetermined sequence that has been subjected to sterilization, deimmunization, or disinfection;

FIG. 21 is a homology comparing protein sequences of α-Gliadin from many species of commonly consumed grains;

FIG. 22 shows an example of a Western Blot for a defined α-Gliadin surrogate protein having a predetermined sequence that has been subjected to sterilization, deimmunization, or disinfection.

DETAILED DESCRIPTION OF THE INVENTION

Aside from the preferred embodiment or embodiments disclosed below, this invention is capable of other embodiments and of being practiced or being carried out in various ways. Thus, it is to be understood that the invention is not limited in its application to the details of construction and the arrangements of components set forth in the following description or illustrated in the drawings. If only one embodiment is described herein, the claims hereof are not to be limited to that embodiment. Moreover, the claims hereof are not to be read restrictively unless there is clear and convincing evidence manifesting a certain exclusion, restriction, or disclaimer.

The method for rapidly determining effective sterilization, deimmunization, and/or disinfection of equipment or supplies of one or more embodiments of this invention may be utilized to qualify sterilization, deimmunization, and/or disinfection by a device, e.g., a sterilization device, a deimmunization device, or a disinfection device and provide improvements to the conventional methods discussed above. In one example, the method for rapidly detecting effective sterilization, deimmunization, and/or disinfection of equipment or supplies of one or more embodiments of this invention may be based on a specific measuring the complete destruction of a specific protein critical for an organism's growth and requires only a few hours to return absolute results. The method for rapidly detecting effective sterilization, deimmunization, and/or disinfection of equipment or supplies of one or more embodiments of this invention also contains multiple layers of internal controls that enable a clear determination if either false positive and false negative results have occurred. This allows the avoidance of unnecessary repairs to sterilization, deimmunization, or disinfection equipment and eliminates false negative tests and more dangerous exposure of patients to improperly sterilized, deimmunized, or disinfected medical equipment or supplies.

The method for rapidly detecting effective sterilization, deimmunization, and/or disinfection of equipment or supplies of one or more embodiments of this invention may be used to rapidly determine if a sterilization, deimmunization, and/or disinfection device is effectively destroying specific infectious or immunogenic agents, defined herein as infectious or pathogenic proteins, infectious spore forming bacteria, infectious vegetative bacteria, infectious fungus, infectious viruses, and immunogenic proteins.

In one embodiment, the method for rapidly determining effective sterilization, deimmunization and/or disinfection of equipment and/or supplies by a device, such as a sterilization device, e.g., by a device that applies cycles of a solvent and electromagnetic radiation, e.g., microwaves, such as disclosed in U.S. application Ser. No. 15/330,469 by the assignee hereof, hereinafter the '469 patent application, any of the sterilization devices discussed in the Background section above, the devices for the methods of sterilization shown in Table 3 above, an autoclave, of similar type sterilization device known to those skilled in the art, a deimmunization device, e.g., a device that applies cycles of a solvent and electromagnetic radiation, e.g., microwaves, such as disclosed in the '469 patent application and/or disinfection device, e.g., a device that applies cycles of a solvent and electromagnetic radiation, e.g., microwaves, such as disclosed in the '469 patent application, or the devices for the methods of disinfection shown in Table 3 above, includes providing a defined surrogate protein having a predetermined sequence representative of an infectious agent potentially contaminating the equipment and/or supplies to be sterilized, deimmunized and/or disinfected by the device, step 100, FIG. 1. The defined surrogate protein having the predetermined sequence is then subjected to sterilization, deimmunization, or disinfection, step 102. The effectiveness of the sterilization, deimmunization, and/or disinfection by the device is then rapidly determined by determining if the defined surrogate protein having the predetermined sequence has been destroyed, step 106, as discussed further below.

The method preferably directly measures the irreversible destruction of the defined surrogate proteins having the predetermined sequence that are critical for survival and/or growth of such infectious agents.

In one embodiment, the method utilizes one or more prion detection indicator samples configured as a defined surrogate protein. In this example, the defined surrogate protein has the following predetermined sequence:

(SEQ ID No: 9) KKRPKPGGWN TGGSRYPGQG SPGGNRYPPQ GGTWGQPHGG GWGQPHGGSW 50 GQPHGGSWGQ PHGGGWGQGG GTHNQWNKPS KPKTNLKHVA GAAAAGAVVG 100 GLGGYMLGSA MSRPMIHFGN DWEDRYYREN MYRYPNQVYY RPVDQYSNQN 150 NFVHDCVNIT IKQHTVTTTT KGENFTETDV KMMERVVEQM CVTQYQKESQ 200 AYYDGRRS 208

The defined prion surrogate protein having the predetermined sequence above for prion detection is then subjected to sterilization, deimmunization, or disinfection, by a device, e.g., a sterilization device, a deimmunization device or a disinfection device, e.g., by conventional methods discussed in the Background section above, or by applying cycles of a solvent and electromagnetic radiation, e.g., microwaves, such as disclosed in the '469 patent application.

In this example, to rapidly determine the effectiveness of sterilization, deimmunization, or disinfection of equipment or supplies by the device, a determination is made if the defined surrogate protein has been destroyed using a sensitive protein analysis procedure, such as Western Blot analysis, or similar protein analysis techniques, such as fluorescence analysis of proteins covalently crosslinked to solid surfaces used in protein array analysis which are extremely sensitive processes that measure both the amount of full length intact defined surrogate protein having a predetermined sequence and the amount of the destroyed or degraded defined surrogate protein, protein array analysis, magnetic separation analysis, peptide analysis, mass spectrometry analysis, gas chromatography analysis, or similar type analysis. In one example, the defined surrogate protein includes a protein critical for stability, growth, and/or infectious capacity of an infectious agent. The defined surrogate protein may include a protein critical for stability, growth, and/or infectious capacity of a surrogate organism of the infectious agent.

One embodiment of the method for rapidly detecting effective sterilization, deimmunization, and/or disinfection of this invention includes providing the defined surrogate protein having a predetermined sequence that is based on the development of a synthetic recombinant test protein sequence with high homology to a section of a protein encoded by the suf I loci in the targeted pathogenic genus, e.g., one or more or all of the genus shown in Table 2 above, and the development of a monoclonal or polyclonal antibody that is able to detect the defined surrogate recombinant protein using Western Blot or other similar protein analysis techniques discussed above. In genera that form spores, such as Bacillus and Clostridium, the target protein encoded in the suf I loci or defined surrogate protein having the predetermined sequence of the tests forms the spore coat protein CotA. In non-spore forming genus such as the bacteria Mycobacterium, Staphylococcus and Pseudomonas, or the fungus Candida, the target protein encoded in the suf I loci or defied surrogate protein of the tests forms the cell division protein (FtsP). In other genera of bacteria and fungus, the target protein or encoded defined surrogate protein having the predetermined sequence in the suf I loci may have additional names but all carry the same protein structure of multicopper oxidase with 3 cupredoxin superfamily domains.

For each method of rapidly determining effective sterilization, deimmunization, or disinfection, specific for its unique genus, a predetermined quantity of the defined surrogate having the predetermined protein sequence is placed on a carrier, such as filter paper, or a tube, or on the surface of an object, such as a glass or slide, a microtiter plate, a flexible membrane, magnetic beads, e.g., magnetic beads used for magnetic bead separation or similar type object or surface. For Western analysis, the defined surrogate protein having the predetermined sequence is not covalently linked to the carrier or surface. In other protein analysis processes such as protein array or magnetic bead separation, the defined surrogate protein having the predetermined sequence is covalently linked to the carrier or solid surface. After treatment with the sterilization, deimmunization or disinfection equipment of process and Western analysis, this involves recovering the recombinant defined surrogate protein having the predetermined sequence, both in its intact and fragmented forms, from the carrier, surface tube, or object, treating the sample with denaturing loading buffer and running the sample on an acrylamide gel. A control sample that was not subjected to sterilization, deimmunization, or disinfection is also included. In one example, the samples are transferred nylon membrane and the intact and fragmented samples are visualized using the specific antibody. If the sterilization, deimmunizing or disinfection equipment is operating correctly, the control sample will have protein indicator bands that are easily visualized but the treated sample will be absent any type protein indicator bands indicating the sterilization, deimmunizing or disinfection equipment was able to irreversibly fragment the recombinant defined surrogate protein. If other protein analysis processes such as protein array or magnetic bead separation are used, the solid surface to which defined surrogate protein having the predetermined sequence was covalently linked will be tested such that intact defined surrogate protein having the predetermined sequence can be visualized using the specific antibody and fragment and/or destroyed defined surrogate protein having the predetermined sequence is no longer detected by the process. As the amino acid sequence and structure of the defined surrogate protein having a predetermined sequence is highly homologous to the target protein in the pathogenic members of the genus, irreversible destruction of the defined surrogate protein indicates that the sterilization, deimmunizing or disinfection equipment will have also destroyed the target proteins, resulting in destruction of all members of the genus that may be on the sterilization, deimmunizing or disinfection equipment or supplies.

In accordance with one or more embodiments of the method for rapidly determining effective sterilization, deimmunization, and/or disinfection, the predetermined sequence of the defined surrogate protein and the corresponding peptide used for development of a polyclonal antibody for Western Blot analysis include one or more of the following predetermined sequences:

For Clostridium:

(SEQ ID NO: 1)         10          20          30          40          50 MYNYTSAKYE  VPIAIQDRSF  NEDGSLNFPS  EGDNPTIHPY  WQPEFFGDTI MVNGRVWPNM  NVDMTRYRFR  LLNGSNARFY  NLKFSNGMQF  WQIGTDGGYL NKPVPLTSLL  ISPGERADIL  VDFTEIPAGT  RIILNNDANA  PYPTGDAPDK DTTGQIMQFT  VQHNDHHHHH  H

The peptides used for the development of polyclonal and monoclonal antibodies for use by Western Blot analysis for the above sequence are:

(SEQ ID NO: 10) KYEVPIAIQDRSFNEDGSLNFPSE and (SEQ ID NO: 11) YLNKPVPLTSLLISPGERADILVD

For Bacillus:

(SEQ ID NO: 2)         10          20          30          40          50 MTLEKTYYEV  TMEECTHQLH  RDLPPTRLWG  YNGLFPGPTI  EVKRNENVYV KWMNNLPSTH  FLPIDHTIHH  SDSQHEEPEV  KTVVHLHGGV  TPDDSDGYPE ANFSKDFEQT  GPYFKREVYH  YPNQQRGAIL  WYHDHAMALT  RLNVYAGLVG AYIIHDPKEK  RLKHHHHHH

The peptides used for the development of polyclonal mid monoclonal antibodies for use by Western Blot analysis for the above sequence are:

(SEQ ID NO: 12) QRGAILWYHDHAMALTRLNVYAGL and (SEQ ID NO: 13) QLHRDLPPTRLWGYNGLFPGPTIE

For Mycobacterium:

(SEQ ID NO: 3)         10          20          30          40          50 MTGMPEGEGV  DSNLLGGDGG  DIAYPYYLIN  GRIPVAATSF  KAKPGQRIRI RIINSAADTA  FRIALAGHSM  TVTHTDGYPV  IPTEVDALLI  GMAERYDVMV TAAGGVFPLV  ALAEGKNALA  RALLSTGAGS  PPDHHHHHH

The peptides used for the development of polyclonal and monoclonal antibodies for use by Western Blot analysis for the above sequence are:

(SEQ ID NO: 14) DTAFRIALAGHSMTVTHTDGYPVIPTEVD and (SEQ ID NO: 15) VFPLVALAEGKNALARALLSTGAGS

For Staphylococcus:

(SEQ ID NO: 4)         10          20          30          40          50 MTGYKNYTLK  AQKGKTEFYK  NNFSNTLGYN  GNLLGPTLKL  KKGDKVKIKL INNLDENTTF  HWHGLEVNGK  VDGGPSQVIK  PGKEKTIKFE  VNQDSATLWY HPHPSPNTAK  QVYNGLSGLL  YIEDSKKNHH  HHHH

The peptides used for the development of polyclonal and monoclonal antibodies for use by Western Blot analysis for the above sequence are:

(SEQ ID NO: 16) NFSNTLGYNGNLLGPTLKLKKGDKVKIKL and (SEQ ID NO: 17) KFEVNQDSATLWYHPHPSPNTAK

For Pseudomonas:

(SEQ ID NO: 5)         10          20          30          40          50 MTGFRHEKVL  CLKTWHVDEQ  GAFTPFSVPR  QAAREGTRGR  YSTINGKHVP TIDLPAGQIV  RVRLLNVDNT  VTYRLNPNGE  ARIYAVDGHP  VEPRGFEGQY WIGPGMRLEL  ALKVPEAGTE  LSLRDGPVRL  ATIRSVAHHH  HHH

The peptides used for the development of polyclonal and monoclonal antibodies for use by Western Blot analysis for the above sequence are:

(SEQ ID NO: 18) DLPAGQIVRVRLLNVDNTVTYRLN and (SEQ ID NO: 19) QYWIGPGMRLELALKVPEAG

For Trichophyton:

(SEQ ID NO: 6)         10          20          30          40          50 MTITLEWSVT  TGYRRLDGVK  KRVYLINGLF  PGPTIEARSG  DSLQVQVTNN IQDEGLVIHW  HGLHMRGANH  MDGVTGVTQC  PIVPGDSMLY  NFTISQSQSG TFWYHAHSAL  QRAEGLYGGF  VVHKPSTHHH  HHH

The peptides used for the development of polyclonal and monoclonal antibodies for use by Western Blot analysis for the above sequence are:

(SEQ ID NO: 20) YRRLDGVKKRVYLINGLFPGPTIE and (SEQ ID NO: 21) TQCPIVPGDSMLYNFTISQSQSG

For Candida:

(SEQ ID NO: 7)         10          20          30          40          50 MTAETHTWYF  KTSWVDANPD  GVFPRKMIGF  NDSWPLPTLR  VKKGDTVNLY LINGFDDRNT  SLHFHGLFQH  GTNQMDGPEM  VTQCPIPPGE  TFLYNFTVDD QVGSYWYHSH  TSGQYGDGMR  GVFIIEDHHH  HHH

The peptides used for the development of polyclonal and monoclonal antibodies for use by Western Blot analysis for the above sequence are:

(SEQ ID NO: 22) GFNDSWPLPTLRVKKGDTVNLYL and (SEQ ID NO: 23) WYFKTSWVDANPDGVFPRKMIG

For α-Gliadin:

(SEQ ID NO: 8)         10          20          30          40          50 MKTVRVPVPQ  PQPQNPSQPQ  PQRQVPLVQQ  QQFPGQQQQF  PPQQPYPQPQ PFPSQQPYLQ  LQPFPQPQPF  PPQLPYHHHH  HH

The peptide used for the development of monoclonal or polyclonal antibody used by Western Blot analysis for the above sequence is:

(SEQ ID NO: 24) FPPQQPYPQPQPFPSQQPYLQLQPFPQPQ

Western Blot analysis typically utilizes equipment, e.g., acrylamide gel, a power supply to create an electric field to trigger protein migration where smaller fragments move faster than larger fragments to separate intact proteins from fragmented or degraded proteins, a membrane, transfer equipment, and visualization equipment. Western Blot analysis also preferably utilizes specific reagents, e.g., a positive control protein to show the location of a full length defined surrogate protein and specific antibody for the defined surrogate protein, e.g., any of the defined surrogate proteins having the associated predetermined sequences and the corresponding antibody above. The specific antibody binds to the associated defined surrogate protein, both full length, and fragments, to provide a visualization if the defined surrogate protein was destroyed by sterilization, deimmunization, or disinfection.

Western Blot analysis for infectious organisms may also typically include a defined number of colony forming units (CFU) or spores of the test pathogen which are added to a stable substrate such as filter paper (dried) or other sample holder. The number of CFU or spores will contain a defined quantity of each indication protein to be followed.

Western Blot analysis may also be conducted on defined surrogate proteins having the associated predetermined sequences samples placed on indicator strips or other small sample holders that maybe subjected to sterilization, deimmunization or disinfection. After sterilization, deimmunization or disinfection, the defined surrogate proteins from the indicator strips or other small sample holders are extracted from the filter paper or other sample holders into a loading dye and denatured (eliminating any tertiary protein structure). The samples are then run on the gel, including control wells with (1) size marker, (2) positive control protein, (3) other controls if needed. After transfer to membrane, defined surrogate proteins and protein fragments are visualized with unique antibodies preferably having a high affinity and specific binding to an indicator region of the protein being tested. Successful sterilization, deimmunization or disinfection will result in the loss of all indicator proteins of defined length. The development process may require side by side Western Blots and standard growth studies to demonstrate sufficient equivalence.

Western Blot analysis may also require defining the defined surrogate proteins having the associated predetermined sequence, positive control proteins, and/or a negative control proteins and may require the development of a polyclonal or monoclonal antibodies that specifically bind to specific defined surrogate proteins discussed above in Western Blot analysis or other protein analysis format, both full-length and fragments, and the positive control protein. The antibody will not bind to the negative control protein. It is also possible that a secondary antibody that is labeled with an enzyme or other visualization marker will be needed to visualize the detection antibody.

Protein array analysis can be used as a substitution for Western blot analysis in circumstances in which less sensitivity can be tolerated, but faster results are needed. In a Western Blot analysis, a substrate such as a piece of filter paper ortube is used to temporarily hold the recombinant protein sample during testing of sterilization equipment. After sterilization, deimmunization and/or disinfection, the recombinant protein sample is removed from the substrate, denatured, separated on an acrylamide gel and transferred to nylon membrane before visualizing with antibodies. In protein array analysis, the recombinant protein sample, e.g., one or more of the defined surrogate proteins having the associated predetermined sequence discussed above, is covalently crosslinked to solid surfaces such as glass, plastics or metal beads. After treatment by sterilization, deimmunization or disinfection, the solid surfaces, with the covalently crosslinked recombinant proteins are directly visualized with antibodies. Unlike Western blot analysis that can visualize the amount of protein fragmentation has occurred, protein array analysis can indicate how much of the protein sample has lost regions that are recognized by visualizing antibodies protein assay analysis but is unable to determine what other areas of the recombinant proteins were not destroyed. Thus, protein array analysis is highly suitable for testing the presence or absence of intact test proteins, such as the defined surrogate proteins having the associated predetermined sequence homologous to proteins critical for spore coats or bacteria or fungus survival or growth, e.g., one or more of the defined surrogate proteins having the predetermined sequences for Clostridium, Bacillus, Mycobacterium, Staphylococcus, Pseudomonas, Trichophyton, Candida, and α-Gliadin shown above. Because protein assay analysis cannot determine the absolute level of protein fragmentation that has occurred, protein array analysis may not be sensitive enough for quantifying the complete destruction of infectious proteins like prions although it is not excluded as a test method if less sensitivity is tolerated.

To establish a protein array analysis, defined quantities of the defined surrogate proteins for Clostridium, Bacillus, Mycobacterium, Staphylococcus, Pseudomonas, Trichophyton, Candida, and α-Gliadin above are covalently linked to a solid surface. The solid surface may include a wide support surface, such as a microscope slide made of glass or silicon, a flexible membrane, a magnetizable bead, a microtiter plate, or other similar solid surface to which a selection of the defined surrogate proteins having the associated predetermined sequence can be permanently attached. The surface used is determined by the type detector that will be used to determine the quantity of protein left on the support after sterilization, deimmunization or disinfection. After sterilization, deimmunization or disinfection, the solid surface is visualized with antibodies or other specific ligands that will specifically bind to the intact defined surrogate protein but not to destroyed defined surrogate proteins. The antibodies or other ligands can contain fluorescent dyes or other detection enabling attachments. Control slides that were not subjected to sterilization, deimmunization and/or disinfection are included as a positive control to enable estimations for the relative amount of test protein destroyed by sterilization, deimmunization and/or disinfection. FIG. 2 shows an example of multi-well glass slide 130 which has the control defined surrogate protein having the associated predetermined sequence in the wells exemplarily, indicated at 132 and multi-well glass slide 134 which has one of the defined surrogate proteins having the predetermined sequence for Clostridium, Bacillus, Mycobacterium, Staphylococcus, Pseudomonas, Trichophyton, Candida, and α-Gliadin in the wells, exemplarily indicated at 136. In this example, control multi well glass slide 130 was not subject to sterilization, deimmunization, or disinfection and visualization of the antibodies is indicated by the shading as shown which indicates the defined surrogate protein having the associated predetermined sequence was not sterilized, deimmunized, or disinfected. In this example, multi-well glass slide 134 was subject to sterilization, deimmunization and/or disinfection and visualization shows no presence of antibodies and, therefore, the defined surrogate proteins having the predetermined sequence were effectively sterilized. Thus, in this embodiment, the method for rapidly determining effective sterilization was able to quickly determine effective sterilization, deimmunization and/or disinfection in as little as two hours depending on the type of detection equipment used to rapidly determine effective sterilization, deimmunization or disinfection discussed above.

One key benefit of using protein array analysis in accordance with one embodiment of the method for rapidly determining effective sterilization, deimmunization, and/or disinfection of this invention is the covalently linked surrogate proteins on the surface of an object can be used for testing sterilization, deimmunization or disinfection by a sterilization, deimmunization or disinfection device that may use radiation or heat, as well as devices that use flowing disinfectants or gases to sterilize, deimmunize or disinfect medical equipment or supplies. In one example, holder 150, FIG. 3, may be used to hold multiwall glass slide 152 having one or more wells, exemplarily indicated at 154, which each holds one or more samples of the defined surrogate protein having the predetermined sequence discussed above, e.g., one of Clostridium, Bacillus, Mycobacterium, Staphylococcus, Pseudomonas, Trichophyton, Candida or α-Gliadin. Holder 150 with multi-well glass slide 152 including one or more samples of the defined surrogate protein having the predetermined sequence discussed above may then be placed below flow 156 of sterilization, deimmunization, or disinfection agent at the end of a medical device undergoing sterilization, deimmunization, or disinfection, indicated at 158. After the test is complete, holder 150 is then removed, indicated at 160, and multi-well glass slide 152 can be easily transferred for complete protein analysis and for rapid detection of sterilization, deimmunization, or disinfection as discussed above.

If magnetizable beads are used as the solid surface, one or more of the defined surrogate proteins having the associated predetermined sequence could also be mixed into liquid sterilization, deimmunization and/or disinfection steam and later harvested with a strong magnet. Flowing disinfectants or gases would result in the complete loss of the defined surrogate protein having the associated predetermined sequence samples that are not covalently linked to a support surface and the protein array analysis may be used to rapidly determine effective sterilization, deimmunization or disinfection.

Both Western Blot Analysis and protein array analysis are an indirect measurement of sterilization, deimmunization and/or disinfection. Sterilization is the complete destruction of spore forming infectious organisms so the standard direct measurements are long growth studies to determine the number of organisms that survived the sterilization process. Deimmunization is the complete destruction of immunogenic proteins such that no protein fragments capable of triggering an immune reaction in human or animal remain. Disinfection is the complete destruction of vegetative bacteria, fungus and/or viruses. As disclosed herein, the defined surrogate proteins are considered to be in the form of isolated fragments and destroyed if proteins critical for the survival of the infectious agents are used in quantities 10,000 to 1,000,000 times as much as would occur in a standard sample of intact infectious agents. To correctly establish the scale to determine success ratio between the direct and indirect tests, multiple conditions are preferably utilized to determine the Western Blot analysis and protein array analysis conditions that perfectly align with standard sterilization, deimmunization and/or disinfection studies using intact infectious organisms and post sterilization growth conditions.

The samples prepared for Western Blot analysis and protein array analysis may use a wide range of circumstances. If the sterilization, deimmunization and/or disinfection equipment uses flowing gases or liquid to wash over the surfaces to be sterilized holder 150, FIG. 3, and multi-well glass slide 152 or similar type device, may be used to ensure the defined surrogate protein samples remain in the flowing stream of disinfecting gas or liquid. For example, if the sterilization, deimmunization or disinfecting gas or liquid is washed through medical equipment to sterilize, deimmunize, or disinfect the inside of a lumen, holder 150 with the multi-well glass slide 150 having one or more defined surrogate proteins having the associated predetermined sequence therein, e.g., Clostridium, Bacillus, Mycobacterium, Staphylococcus, Pseudomonas, Trichophyton, Candida, and α-Gliadin analysis tests could be connected to the end of the stream to better measure the quality of sterilization, deimmunization, or disinfection that occurred through the entire length of the medical equipment lumen.

The following examples are exemplary and explanatory only and do not limit or restrict this invention.

EXAMPLES Example 1: Comparing Amino Acid Sequence of Human PrP Protein to Other Species

It is important to qualify the ability of a sterilization device to destroy prions that may be contaminating medical equipment. For the specific test described herein in accordance with one or more embodiments of the method for rapidly determining effective sterilization, deimmunization, or disinfection of this invention, a defined quantity of the defined surrogate prion protein discussed above is provided and then evaluated using Western Blot analysis and an antibody specific for the defined prion surrogate protein.

To protect the human operators of the test, infectious human prions cannot be used. Instead, the defined surrogate protein is used that incorporates all the characteristics of human prion (PrP) proteins, with the critical exception that it cannot infect humans. In this example, to select the defined surrogate PrP protein to be used, a protein analysis was conducted comparing the amino acid protein sequence of human PrP protein against a selection of the protein sequence databases of other species including a primate, two companion animals, two food animals and two research animals. From this analysis, the mouse PrP protein was determined to be the best candidate surrogate protein. Structurally, mouse PrP protein is as robust as the human PrP protein and thus will be equivalently resistant to a wide range of destructive methods but is also sufficiently different as to be unable to infect humans. Arrow 168, FIG. 4, indicates the initiation location for Pr27-30, the smallest PrP fragment that retains infectivity. If a PrP protein is cleaved anywhere from this initiation point to the end of the protein sequence, the resulting fragments can no longer cause disease.

To evaluate additional surrogate PrP proteins that could be used, the mouse PrP protein sequence was compared against the protein sequence database. Table 5 below shows the wide diversity of a predetermined list of species PrP proteins that could be used as well as each protein's sequence ID and its homology to Mouse PrP. The human sequence is less than 90% homologous to mouse PrP. The search also demonstrates how conserved the PrP protein is across a wide range of mammalian species contained within the sequence database and any one of these could be used as the surrogate protein in the Protein Indicator Test. The database also contains the sequence for chicken PrP but as it is less than 50% homologous to other mammalian PrP proteins, it is possible that it or other related proteins could be used in the Protein Indicator Test but its divergence could impact its resistance to destruction. This would make it a less suitable surrogate for the test than other proteins, especially any mammalian PrP protein.

TABLE 5 Potential PrP Protein that could be used as Surrogate Protein in Sterilization Indication Tests. Information about each PrP protein includes species, Sequence ID number and homology to Mouse recombinant PrP protein. Homology to Species Sequence ID Number Mouse (%) Mouse (Mus musculus) sp|P04925.2|PRIO_MOUSE 100 Rat (Rattus norvegicus) sp|P13852.2|PRIO_RAT 98 Cotton Rat (Sigmodon hispidus) sp|Q9Z0T3.1|PRIO_SIGHI 97 Chinese Hamster (Cricetulus griseus) sp|Q60506.1|PRIO_CRIGR 97 Grey Dwarf Hamster (Cricetulus migratorius sp|Q60468.1|PRIO_CRIMI 95 Golden Hamster (Mesocricetus auratus) sp|P04273.1|PRIO_MESAU 95 Greater Kudu (Tragelaphus strepsiceros) sp|P40243.1|PRIO2_TRAST 90 Red-bellied Titi (Callicebus moloch) sp|P40248.1|PRIO_CALMO 96 Three-striped Night Monkey (Aotus trivirgatus) sp|P40245.1|PRIO_AOTTR 94 Black-capped capuchin (Sapajus apella) sp|P40249.1|PRIO_CEBAP 95 Common Marmoset (Callithrix jacchus) sp|P40247.1|PRIO_CALJA 95 Red-faced Spider Monkey (Ateles paniscus) sp|P51446.1|PRIO_ATEPA 94 Geoffrey's Spider Monkey (Ateles geoffroyi) sp|P40246.1|PRIO_ATEGE 91 Nilgai (Boselaphus tragocamelus) sp|Q5UJG7.1|PRIO_BOSTR 86 Alpine Musk Deer (Moschus chrysogaster) sp|Q68G95.1|PRIO_MOSCH 88 Common Squirrel Monkey (Saimiri sciureus) sp|P40258.1|PRIO_SAISC 91 Gelada Baboon (Theropithecus gelada) sp|Q95270.1|PRIO_THEGE 90 Black Crested Mangabey(Lophocebus aterrimus) sp|P67990.1|PRIO_LOPAT 90 Mona Monkey(Cercopithecus mona) sp|P61761.1|PRIO_CERMO 91 Patas Monkey(Erythrocebus patas) sp|Q95174.1|PRIO_ERYPA 91 Grivet(Chlorocebus aethiops) sp|P67988.1|PRIO_CHLAE 90 Mantled Guereza(Colobus guereza) sp|P40251.1|PRIO_COLGU 91 Bornean orangutan(Pongo pygmaeus) sp|P40256.1|PRIO_PONPY 91 François' Langur (Trachypithecus francoisi) sp|P40257.2|PRIO_TRAFR 91 Sooty Mangabey (Cercocebus atys) sp|Q95176.1|PRIO_CERAT 91 Crab-eating Macaque (Macaca fascicularis) sp|P67992.1|PRIO_MACFA 91 Mandrill(Mandrillus sphinx) sp|P40255.1|PRIO_MANSP 91 Gorilla (Gorilla gorilla gorilla) sp|P40252.1|PRIO_GORGO 90 Cat (Felis catus) sp|O18754.3|PRIO_FELCA 87 Human (Homo sapiens) sp|P04156.1|PRIO_HUMAN 89 Lar Gibbon(Hylobates lar) sp|P61766.1|PRIO_HYLLA 89 Bighorn Sheep (Ovis canadensis) sp|Q7JIH3.1|PRIO_OVICA 88 Goat(Capra hircus) sp|P52113.1|PRIO_CAPHI 88 Blackbuck(Antilope cervicapra) sp|Q5UJG1.1|PRIO_ANTCE 85 Takin(Budorcas taxicolor) sp|Q95M08.1|PRIO_BUDTA 87 Sheep (Ovis aries) sp|P23907.1|PRIO_SHEEP 87 Rabbit (Oryctolagus cuniculus) sp|Q95211.1|PRIO_RABIT 90 Water Buffalo (Bubalus bubalis) sp|Q5UJH8.1|PRIO_BUBBU 84 Rocky Mountain Elk sp|P67986.1|PRIO_CEREN 87 (Cervus canadensis nelsoni) Mule Deer (Odocoileus hemionus) sp|P47852.1|PRIO_ODOHE 87 Lesser Kudu (Tragelaphus imberbis) sp|Q5UJG3.1|PRIO_TRAIM 85 Greater Kudu(Tragelaphus strepsiceros) sp|P40242.1|PPIO1_TRAST 84 Cow (Bos taurus) sp|P10279.2|PRIO_BOVIN 84 Common Brushtail Possum sp|P51780.1|PRIO_TRIVU 77 (Trichosurus Vulpecula) Giant Panda(Ailuropoda melanoleuca) sp|Q6EH52.1|PRIO_AILME 84 American Mink (Neovison vison) sp|P40244.1|PRIO_NEOVI 79 Dromedary Camel (Camelus dromedaries) sp|P79141.1|PRIO_CAMDR 88 Pig (Sus scrofa) sp|P49927.1|PRIO_PIG 79 Ferret(Mustela putorius furo) sp|P52114.1|PRIO_MUSPF 78 Artic Fox(Vulpes lagopus) sp|B0FYL5.1|PRIO_VULLA 78 Dog (Canis lupus familiaris) sp|O46501.1|PRIO_CANFA 85 Chicken (Gallus gallus) sp|P27177.2|PRIO_CHICK 43

Example 2: Developing Method for Testing the Ability to Destroy PrP Proteins

One purpose of developing the defined prion surrogate protein test is to provide a rapid method for determining effective sterilization equipment. The method preferably has multiple steps including at least: 1) preparing defined prion surrogate proteins having a predetermined sequence, 2) subjecting the prion surrogate protein samples to sterilization, and 3) using Western Blot analysis to visualize the effects of sterilization of defined prion surrogate protein samples. Successful sterilization has occurred when all of the defined prion surrogate protein sample was fragmented and, as a result of the protein fragmentation, none remains to bind to the visualization antibodies. If sterilization was not successful, protein bands will be see on the Western Blot analysis.

A defined surrogate protein having a sequence above for the prions, recombinant mouse PrP full-length protein (208 amino acids long) was obtained from Abcam, Cambridge Mass. On a Western gel, the recombinant protein runs at about approximated 28 kDa in size, indicated at 290, FIG. 5.

The Western Blot analysis discussed above is well-established and is an extremely sensitive method to determine the presence and/or absence of a specific protein. The first step in Western Blot analysis involves preparing the defined prion surrogate protein samples for separation by size. In accordance with one embodiment of the method for rapidly determining effective sterilization, deimmunization, or disinfection of the defined prion surrogate proteins will be run as single denatured proteins and thus must be denatured through the use of a denaturing loading buffer, boiled for 10 minutes and then run on a denaturing gel. Once loaded on to an appropriate acrylamide gel, the samples are subjected to electric current that results in the protein fragments traveling at different rates depending on size with smaller fragments moving faster than larger ones. In one example, the gel contained 8% acrylamide. To be able to monitor the separation of the defined prion surrogate protein samples, a standard sample with a mix of proteins of defined sizes was also included. For some experiments discussed herein, additional protein samples may be included to provide for controls of the sample handling conditions:

After separation, the defined prion surrogate protein samples are transferred to a special nylon membrane before being permanently cross-linked to the membrane. The final steps include incubating the nylon membrane with a primary antibody available from Abeam, Cambridge Mass. that specifically binds to the defined surrogate protein of interest. In the experiments discussed herein, the primary anti-PrP antibody was a rabbit monoclonal antibody that was raised against a synthetic peptide corresponding to residues near the C-terminus of human Prion protein PrP, as indicated by underlined region indicated at 170, FIG. 4. In addition to binding to both PrP_(c) and PrP_(sc), the antibody will bind to the infectious protein form PrP 27-30. The primary antibody binds to Human, Rat and Mouse PrP proteins. The secondary antibody is a HRP-labelled goat anti-rabbit available from Abcam, Cambridge Mass. to enable visualization of the infectious PrP fragments, both intact and fragmented. If the defined prion surrogate proteins have been fragmented into non-infectious fragments that eliminate the C-terminus region of the PrP, the antibody will not bind them. Without this C-terminus region, the degraded PrP protein is no longer infectious. Very small fragments and amino acids which are no longer infectious will be too small to be retained on the gel.

The first tests involved carefully drying defined quantities of recombinant mouse PrP protein onto filter papers to assist in storage, transport to and from location of sterilization equipment and handling during sterilization tests. To create, test strips of filter paper were cut 4 mm wide by 20 mm long and the bottoms were squared. Serial dilutions (1:3) of mouse PrP protein were created to contain protein solutions 0.1 μg/μl to 0.0037 μg/μl. The protein preps were added dropwise to the filter paper strips until 10 ul were added. The filter paper strips were then air dried. Filter paper strips were prepared in duplicate with 1 μg, 0.333 μg, 0.111 μg, or 0.033 μg applied respectively to a pair of strips. When dry, the strips were placed in Eppendorf tubes and 50 ul 1× Loading Buffer where BME was added. The strips and loading buffer were incubated at 95° C. for 5 minutes then given a quick spin in a micro centrifuge. For one of each paired sample, the filter paper strip was taken out of the Eppendorf tube and inserted into the well of the SDS-PAGE gel. For these samples, electroporation was used to extract any residual defined prion surrogate protein that was retained on the filter paper after extraction by boiling and centrifugation. Half of the loading buffer from these tubes was also loaded into the same well. For the other samples of the pair only boiling and centrifugation was used to extract the defined prion surrogate protein from the filter strips. From these, half of the loading buffer was added to the wells without also adding the filter paper. A control sample of 0.5 μg protein (equivalent to half of the 1 μg concentration samples) was also loaded on the gel for comparison. The gel was run and the Western Blot Analysis performed using the procedure described above.

The results demonstrated that there was no significant difference between the protein concentrations that were dried onto the filter paper and the control sample. There was also no significant difference between the extraction process using only boiling and centrifugation and the more difficult process of using boiling, centrifugation and electroporation for extraction. In addition, the Western Blot analysis demonstrated that the Western Blot analysis was sensitive to below 0.05 μg. Hence, a 1 μg of recombinant mouse PrP protein should be used for all sterilization tests. The samples should be extracted from filter paper using boiling in loading the buffer with BME and centrifugation and half of the sterilized samples used for Western Bolt analysis.

Example 3: Evaluation of Destruction of Prion Proteins Using Sterilization Equipment

Experiments were conducted to demonstrate a combination of one or more of heat, a vaporizing solvent, and electromagnetic radiation, e.g., microwaves, e.g., as disclosed in the '469 patent application, could irreversibly destroy the defined prion surrogate protein shown with the sequence shown above. The stable PrP protein was selected for the experiments as it cannot be irreversibly destroyed using a standard sterilization autoclave device. For the experiments, samples were created that each contained 1 μg of a structurally robust mouse PrP protein and wrapped in 100% cotton paper to avoid extraneous contamination. This containment was placed in a second layer of 100% cotton paper to increase stability during treatment. The samples were treated with different temperatures and for differing numbers of moisture saturation and microwave cycles, e.g., as disclosed in the '469 patent application. After treatment, the samples were prepared in loading buffer and boiled. Half of each sample was then run on a denaturing protein gel. After Western Blot analysis, it was possible to see that certain combinations of temperature and treatment cycles completely destroyed the stable protein samples, shown by the absence of protein bands of gel indicated at 294, 296, FIG. 6. Other treatment conditions did not destroy the stable proteins.

Example 4: Evaluation of Destruction of Prion Proteins Contained within Polypropylene Tubes

Additional experiments were conducted to demonstrate that with the combination of one or more of heat, saturating moisture and microwaves as disclosed in the '469 patent application could destroy the defined surrogate stable PrP proteins if the samples were contained within a vessel such as a polypropylene tube. In this example, samples of the defined prion surrogate proteins were created that each contained about 1 μg of a structurally robust mouse protein. However, instead of drying the protein samples onto filter paper, the 1 μg samples were dried within polypropylene tubes of different lengths including 0.75 cm and 3.5 cm in length. The tubes were closed at one end (on to which the samples were dried) and open at the other. The tubes were contained within 2 layers of 100% cotton paper to prevent cross contamination during treatment. The samples were subjected to sterilization by a combination of one or more of heat, a solvent, e.g., reverse osmois (RO) filtered water, and electromagnetic radiation with differing numbers of moisture saturation and radiation cycles, e.g., as disclosed in the '469 patent application. After treatment, the samples were prepared in loading buffer and boiled. Half of each sample was then run on a denaturing protein gel. After Western blot analysis, it was possible to see that certain combinations of temperature and treatment cycles completely destroyed the stable protein samples (as demonstrated by the absence of protein bands of gel). Other treatment conditions did not destroy the stable proteins. The results of the sterilization treatment of PrP samples dried onto filter paper and dried within a polypropylene tube were identical indicating that the method of containing the PrP sample did not alter the results.

Example 5: Comparison of Prion Protein Indicator Test Results and Mouse Model Prion Tests

All mice were kept in an AAALAC-accredited facility and handled in compliance with guidelines provided by the US Guide for the Care and Use of Laboratory Animals.

Creating Prion Infected Brain Homogenate: Brains from terminally ill C57BL/6 mice infected with 22 L prions were prepared as follows: each brain was homogenized (10%, w/v) in phosphate-buffered saline (PBS) by repeatedly passing the material first through an 18-gauge needle and then repeatedly through a 26 gauge needle. The brain homogenates were combined to make a stock preparation, diluted with PBS (1/10), aliquoted into 100 ul preps in 2 ml polypropylene freezing vials and frozen at −80° C. until use.

Division into treated and non-treated preps: frozen prion preps having the defined prion surrogate protein were allowed to thaw and the caps removed. In duplicate, samples were sterilized by a combination of one or more of heat, microwaves and saturating moisture, e.g., as disclosed in the '469 patent application. The used conditions were similar to the process disclosed in Example 4 above. In one example, the sterilization preferably includes: (A) 140° C., 100 cycles of microwave; (B) 100° C., 100 cycles of microwave; and (C) room temperature, 100 cycles with no microwaves. The Prion Protein Indicator Test having the defined surrogate protein samples were analyzed by Western Blot analysis as described in Example 4 above. Depending on treatment conditions, the test sample was completely destroyed (A), partially destroyed (B), or completely intact (C).

Testing infectiveness of Prion Prep: C57BL/6 mice aged 4-5 weeks were divided into 4 cohorts, 10 mice per cohort, to receive the samples that correlated with the following Prion Protein Indicator Test samples having the defined prion surrogate protein: (A) complete destruction; (B) partial destruction; (C) no treatment and (D) PBS control. After anesthesia each mouse was intracerebrally inoculated with a 20 ul-aliquot of the designated inoculum. The mice were observed up to one year after inoculation, unless they displayed terminal symptoms of PrP infection including persistent signs of ataxia, kyphosis, somnolence, and hind leg weakness. Terminally-ill mice were euthanized and their brains divided sagittally along the midline and place formalin fixation for histological analysis or flash-frozen in liquid nitrogen for protein analysis. At one year, all remaining mice (showed no obvious signs of neurologic disease) were euthanized and their brains also divided for histological analysis or protein analysis.

Results: Over the observation period, none of the mice that received either the PBS control (D) or the brain homogenate treated with the conditions that demonstrated complete destruction on the Prion Protein Indicator Test having the defined prion surrogate protein (A) demonstrated any symptoms of disease. After euthanization, none of the brains demonstrated any signs of prion disease. Western Blot analysis of the brains showed no increase in concentrations of PrP proteins over normal levels. The mice that received the brain homogenate and also received no sterilization treatment (C) or partial destruction (B) as indicated by the Priori Protein Indicator Test all demonstrated terminal symptoms of PrP infection before the completion of the 1 year observation period. Their brains demonstrated obvious signs of prion disease and by Western analysis, the concentration of PrP proteins were greatly increased over normal levels. Together the results of the mouse study indicated a clear correlation between the results from the Prion Protein Indicator Test results and the mouse model results.

Example 6: Comparing Amino Acid Sequence of Multiple Members of the Clostridium Genus

It is important to qualify the ability of a sterilization device, a deimmunization device, or a disinfection device to destroy bacteria of any Clostridium species that may be contaminating medical equipment or supplies. In this example, a defined quantity of the defined surrogate protein having the predetermined SEQ ID NO: 1 discussed above was subjected to sterilization, deimmunization, or disinfection to rapidly determine the effectiveness of the sterilization, deimmunization, or disinfection using Western Blot analysis, protein array analysis, or similar type analysis, and the antibody for the defined Clostridium surrogate protein shown above. In this example, to protect the human operators of the test, the defined surrogate protein needs to incorporate critical characteristics of Clostridium proteins that are critical for the survival and growth of members of the Clostridium genus while avoiding organisms that can infect humans.

To design the synthetic defined surrogate, Clostridium protein having the predetermined sequence, SEQ ID NO: 1, a protein analysis was conducted comparing the amino acid sequences of the suf I loci gene from multiple species of the Clostridium genus shown in Table 2 above. In this example, the Sequence IDs (found in Pubmed, www.ncbi.nlm.nih.gov/Pubmed/) for the suf I loci proteins, multiple Clostridium species, used for the comparative are shown in Table 5 below:

TABLE 5 (Clostridium). Sequences used to determine regions of high homology in suf I locus of multiple Clostridium Species. Species Sequence ID Clostridium sporogenes WP_061905762.1 Clostridium botulinum WP_011948579.1 Clostridium novyi WP_039217212.1

The protein produced by the suf I loci is fundamental to survival and growth of a wide range of spores, bacteria and fungus. In species of the Clostridium genus, the protein product of the suf I loci is called cotA and is critical for many live stages including strongly contributing to the stability of the spore coat.

To design the defined Clostridium surrogate protein having SEQ ID NO: 1, the specific amino acids from the proteins listed in Table 5 were aligned to determine amino acid sequence regions that are highly homologous in all evaluated Clostridium species as shown in FIG. 7. The protein encoded by the suf 1 loci includes three cupredoxin domains that are indicated at 200 for domain 1, 202 for domain 2, and 204 for domain 3. In the Clostridium genus, domain 2, indicated at 202, shows high homology between Clostridium species so was used to for the design of the synthetic surrogate protein SEQ ID NO: 1 above to be created for the Clostridium test and the corresponding peptides discussed above were used to develop the polyclonal and monoclonal antibodies for use by Western Blot analysis.

Example 7: Developing Western Test to Qualify Ability to Destroy Clostridium Test Protein

One purpose of developing the synthetic defined Clostridium surrogate protein is to provide a method for rapidly determining the effectiveness of sterilization, deimmunization, and/or disinfection by a device, such as sterilization device, deimmunization device, or disinfection device. In this example, the method for rapidly determining effective sterilization, deimmunization, and/or disinfection includes multiple steps including at least: 1) preparing the synthetic defined Clostridium surrogate protein test samples, 2) subjecting the defined Clostridium surrogate protein test samples to sterilization, deimmunization, or disinfection, and 3) using Western Blot or similar type analysis to visualize the effects of sterilization, deimmunization, or disinfection of defined Clostridium surrogate protein test samples. Successful sterilization, deimmunization, or disinfection has occurred when all the defined Clostridium surrogate protein test samples are fragmented and as a result of the protein fragmentation, none remains to bind to the visualization antibodies indicating the defined Clostridium surrogate protein was destroyed. If sterilization, deimmunization, or disinfection was not successful, protein bands will be seen on the Western Blot analysis.

Following the process more fully described for the Prion test, a similar process was followed to create the Clostridium sterilization, deimmunization, and/or disinfection test. First, to create the sample for the test using the defined Clostridium surrogate protein, DNA encoding the amino acid SEQ ID NO: 1 for Clostridium above was synthesized and cloned into standard vectors both for E. coli and yeast expression. Using standard techniques, large quantities of protein were produced in E. coli or yeast and isolated by standard recombinant methods. Using a nickel column, a full-length defined Clostridium surrogate protein (171 amino acids long) was isolated. To create the samples having the defined Clostridium surrogate protein to qualify sterilization, deimmunization, or disinfection of the samples were dried onto small filter papers, dried inside small tubes or a surface of an object subjected to sterilization, deimmunization, or disinfection e.g., using cycles of applying a solvent and microwave energy as disclosed in the '469 patent application.

After sterilization, deimmunization, or disinfection, the treated Clostridium samples were transferred to tubes, denatured and separated by size and transferred to nylon membrane before being permanently cross-linked to the membrane. The final steps include incubating the nylon membrane with a primary antibody that specifically binds to the defined Clostridium surrogate protein of interest. In the experiments discussed herein, the primary anti-suf I loci encoded protein antibody was a rabbit polyclonal antibody that was raised against a synthetic peptide discussed above for SEQ ID NO: 1 residues. For added sensitivity, addition antibodies, both monoclonal and polyclonal, were raised against the other synthetic peptide(s). For the Western Blot Analysis, a secondary antibody may be a HRP-labelled goat anti-rabbit to enable visualization of the protein fragments, both intact and fragmented. If the defined Clostridium surrogate proteins have completely fragmented no bands will be visualize on the Western blot. Very small fragments and amino acids will be too small to be retained on the gel. When successful sterilization, deimmunization, or disinfection occurred, the visualized Western blot has a dark ban in the untreated control sample, e.g., indicated at 210, FIG. 8, and a complete absence of any bands for the defined Clostridium surrogate protein sample subjected to sterilization, deimmunization, or disinfection indicates successful sterilization, deimmunization, or disinfection, e.g., indicated at 212.

Example 8: Comparing Amino Acid Sequence of Multiple Members of the Bacillus Genus

It is important to qualify the ability of a sterilization device, a deimmunization device or disinfection device to destroy bacteria of any Bacillus species that may be contaminating medical equipment or supplies. In this example, a defined quantity of the defined Bacillus surrogate protein having the predetermined SEQ ID NO: 2 discussed above is subjected to sterilization, deimmunization, or disinfection to rapidly determine the effectiveness of the sterilization, deimmunization, or disinfection using Western Blot analysis, protein array analysis, or similar type analysis, and the antibody for the defined Bacillus surrogate protein shown above. In this example, to protect the human operators of the test, the defined surrogate Bacillus surrogate protein needs to incorporate critical characteristics of Bacillus proteins that are critical for the survival and growth of members of the Bacillus genus while avoiding organisms that can infect humans.

To design the synthetic defined surrogate Bacillus protein having SEQ ID NO: 2, a protein analysis was conducted comparing the amino acid sequences of the suf I loci gene from multiple species of the Bacillus genus shown in Table 2 above. In this example, the Sequence IDs (found in Pubmed, www.ncbi.nlm.nih.gov/Pubmed/) for the suf I loci encoded proteins, multiple Bacillus species, used for the comparative are shown in Table 6 below.

TABLE 6 (Bacillus). Sequences used to determine regions of high homology in suf 1 locus of multiple Bacillus Species. Species Sequence ID Bacillus subtilis AAB62305.1 Bacillus atrophaeus WP_011948579.1 Bacillus pumilus WP_039217212.1

The protein produced by the suf I loci is fundamental to survival and growth of a wide range of spores, bacteria and fungus. In species of the Bacillus genus, the protein product of the suf I loci is called cotA and is critical for many live stages including strongly contributing to the stability of the spore coat.

To design the synthetic defined Bacillus surrogate protein for SEQ ID NO: 2, the specific amino acids from the proteins listed in Table 6 were aligned to determine amino acid sequence regions that are highly homologous in all evaluated Bacillus species as shown in FIG. 9. The protein encoded by the suf 0.1 loci includes three cupredoxin domains, indicated at 214 for domain 1, 216 for domain 2, and 218 for domain 3. In the Bacillus genus, domain 2, indicated at 216, shows high homology between Bacillus species, so SEQ ID NO: 2 above was used as the synthetic defined Bacillus surrogate protein to be used for the Bacillus test and the corresponding peptide discussed above was used to raise a polyclonal antibody for use by Western Blot analysis. Additional polyclonal and monoclonal antibodies were created as needed.

Example 9: Developing Western Test to Qualify Ability to Destroy Bacillus Test Protein

One purpose of developing the synthetic defined Bacillus surrogate protein is to provide a method for rapidly determining the effectiveness of sterilization, deimmunization, and/or disinfection by a device, such as a sterilization device, deimmunization device, or disinfection device. The method for rapidly determining effective sterilization, deimmunization, and/or disinfection preferably includes multiple steps including at least: 1) preparing synthetic defined Bacillus surrogate protein test samples, 2) subjecting the Bacillus surrogate protein test samples to sterilization, deimmunization, or disinfection, and 3) using Western Blot or similar analysis to visualize the effects of sterilization, deimmunization, or disinfection of defined Bacillus surrogate protein test samples. Successful sterilization, deimmunization, or disinfection has occurred when all the defined Bacillus surrogate protein test samples are fragmented and as a result of the protein fragmentation, none remains to bind to the visualization antibodies indicating the defined Bacillus surrogate protein was destroyed. If sterilization, deimmunization, or disinfection was not successful, protein bands will be see on the Western Blot analysis.

Following the process more fully described for the Prion test, a similar process was followed to create the Bacillus sterilization, deimmunization, and/or disinfection test. First, to create the sample for the test using the synthetic defined Bacillus surrogate protein, DNA encoding the amino acid for SEQ ID NO: 2 above was synthesized and cloned into standard vectors both for E. coli and yeast expression. Using standard techniques, large quantities of the defined Bacillus surrogate protein were produced in E. coli or yeast and isolated by standard recombinant methods. Using a nickel column, a full-length defined Bacillus surrogate protein (171 amino acids long) was isolated. To create the samples having the synthetic defined Bacillus surrogate protein to qualify sterilization, deimmunization, and/or disinfection the samples were dried onto small filter papers, dried inside small tubes or a surface of an object subjected to sterilization, deimmunization, or disinfection, e.g., using cycles of applying a solvent and microwave energy, e.g., as disclosed in the '469 patent application.

After sterilization deimmunization and/or disinfection, the treated Bacillus samples were transferred to tubes, denatured and separated by size and transferred to nylon membrane before being permanently cross-linked to the membrane. The final steps include incubating the nylon membrane with a primary antibody that specifically binds to the defined Bacillus surrogate proteins. In the experiments discussed herein, the primary anti-suf I loci protein antibody was a rabbit polyclonal antibody that was raised against a synthetic peptide discussed above for SEQ ID NO: 2 residues. For added sensitivity, addition antibodies, both monoclonal and polyclonal, were raised against the other synthetic peptide(s). For the Western Blot Analysis, a secondary antibody may be a HRP-labelled goat anti-rabbit to enable visualization of the protein fragments, both intact and fragmented. If the defined Bacillus surrogate proteins have completely fragmented no bands will be visualize on the Western blot. Very small fragments and amino acids will be too small to be retained on the gel. When successful sterilization, deimmunization, or disinfection occurred, the visualized Western blot has a dark ban in the untreated control sample, e.g., indicated at 220, FIG. 10, and a complete absence of any bands for defined Bacillus surrogate protein sample subjected to sterilization, deimmunization, or disinfection indicates successful sterilization, deimmunization, or disinfection, indicated at 222.

Example 10: Comparing Amino Acid Sequence of Multiple Members of the Mycobacterium Genus

It is important to qualify the ability of a sterilization device, a deimmunization device, or a disinfection device to destroy bacteria of any Mycobacterium species that may be contaminating medical equipment or supplies. In this example, a defined quantity of the defined surrogate protein having a SEQ ID NO: 3 discussed above is subjected to sterilization, deimmunization, or disinfection to rapidly determine the effectiveness of the sterilization, deimmunization, or disinfection using Western Blot analysis, protein array analysis, or similar type analysis and using an antibody specific for the protein. In this example, to protect the human operators of the test, the defined Mycobacterium surrogate protein needs to incorporate critical characteristics of Mycobacterium proteins that are critical for the survival and growth of members of the Mycobacterium genus while avoiding organisms that can infect humans.

To design the synthetic defined Mycobacterium surrogate protein SEQ ID NO: 3 above, a protein analysis was conducted comparing the amino acid sequences of the suf I loci gene from multiple species of the Mycobacterium genus shown in Table 2 above. In this example, the Sequence IDs (found in Pubmed, www.ncbi.nlm.nih.gov/Pubmed/) for the suf 1 loci proteins, multiple Mycobacterium species, used for the comparative are shown in Table 7 below:

TABLE 7 (Mycobacteria). Sequences used to determine regions of high homology in suf 1 locus of multiple Mycobacterium Species. Species Sequence ID Mycobacterium tuberculosis WP_003404392.1 Mycobacterium africanum KBG17039.1 Mycobacterium kansasii WP_023367763.1

The protein produced by the suf I loci is fundamental to survival and growth of a wide range of spores, bacteria and fungus. In species of the Mycobacterium genus, the protein product of the suf I loci is called cumA and is critical for many live stages including cell survival and growth.

To design the synthetic defined Mycobacterium surrogate protein having SEQ ID NO: 3, the specific amino acids from the proteins listed in Table 7 were aligned to determine amino acid sequence regions that are highly homologous in all evaluated Mycobacterium species as shown in FIG. 11. The protein encoded by the suf 1 loci includes three cupredoxin domains that are indicated at 230 for domain 1, 232 for domain 2, and 234 for domain 3. In the Mycobacterium genus, domain 2, indicated at 232, shows high homology between Mycobacterium species so SEQ ID NO: 3 above was used to for the design for synthetic defined Mycobacterium surrogate protein to be created for the Mycobacterium test and the corresponding peptide for the defined Mycobacterium surrogate protein discussed above was used for a polyclonal antibody for use by Western Blot analysis.

Example 11: Developing Western Test to Qualify Ability to Destroy Mycobacterium Test Protein

One purpose of developing the defined Mycobacterium surrogate protein is to provide a method for rapidly determining the effectiveness of sterilization, deimmunization, and/or disinfection by a device, such as a sterilization device, a deimmunization device, or a disinfection device. The method for rapidly determining effective sterilization, deimmunization, and/or disinfection preferably includes multiple steps including at least: 1) preparing the defined Mycobacterium surrogate protein test samples, 2) subjecting the defined Mycobacterium surrogate protein test samples to sterilization, deimmunization, or disinfection, and 3) using Western Blot or similar analysis to visualize the effects of sterilization, deimmunization, and/or disinfection of synthetic defined Mycobacterium surrogate protein test samples. Successful sterilization, deimmunization, and/or disinfection has occurred when all the synthetic defined Mycobacterium surrogate protein test samples are fragmented and as a result of the protein fragmentation, none remains to bind to the visualization antibodies indicating the defined Mycobacterium protein was destroyed. If sterilization, deimmunization, and/or disinfection was not successful, protein bands will be see on the Western Blot analysis.

Following the process more fully described for the Prion test, a similar process was followed to create the Mycobacterium sterilization, deimmunization, and/or disinfection test. First, to create the sample for the test using the defined Mycobacterium surrogate protein, DNA encoding the amino acid SEQ ID NO: 3 above was synthesized and cloned into standard vectors both for E. coli and yeast expression. Using standard techniques, large quantities of protein were produced in E. coli or yeast and isolated by standard recombinant methods. Using a nickel column, a full-length synthetic Mycobacterium surrogate protein (171 amino acids long) was isolated. To create the samples having the Mycobacterium surrogate protein to qualify sterilization, deimmunization, and/or disinfection the samples were dried onto small filter papers, dried inside small tubes or a surface of an object subjected to sterilization, deimmunization, and/or disinfection, e.g., using cycles of applying a solvent and microwave energy as disclosed in the '469 patent application.

After sterilization, deimmunization, and/or disinfection the treated Mycobacterium surrogate protein samples were transferred to tubes, denatured and separated by size and transferred to nylon membrane before being permanently cross-linked to the membrane. The final steps include incubating the nylon membrane with a primary antibody that specifically binds to the protein of interest. In the experiments discussed herein, the primary anti-suf I loci protein antibody was a rabbit polyclonal antibody that was raised against a synthetic peptide discussed above for SEQ ID NO: 3 for Mycobacterium above residues. For added sensitivity, addition antibodies, both monoclonal and polyclonal, were raised against the other synthetic peptide(s). For the Western Blot Analysis, a secondary antibody may be a HRP-labelled goat anti-rabbit to enable visualization of the protein fragments, both intact and fragmented. If the Mycobacterium surrogate proteins have completely fragmented no bands will be visualize on the Western blot. Very small fragments and amino acids will be too small to be retained on the gel. When successful sterilization, deimmunization, and/or disinfection has occurred, the visualized Western blot has a dark ban in the untreated control sample, e.g., indicated at 236, FIG. 12, and a complete absence of any bands for the Mycobacterium surrogate protein sample subjected to sterilization, deimmunization, or disinfection indicates successful sterilization, deimmunization, or disinfection, e.g., indicated at 238.

Example 12: Comparing Amino Acid Sequence of Multiple Members of the Staphylococcus Genus

It is important to qualify the ability of a sterilization device, a deimmunization device, or a disinfection device to destroy bacteria of any Staphylococcus species that may be contaminating medical equipment or supplies. In this example, a defined quantity of the defined Staphylococcus surrogate protein having the predetermined SEQ ID NO: 4 discussed above is subjected to sterilization, deimmunization, or disinfection to rapidly determine the effectiveness of the sterilization, deimmunization, or disinfection using Western Blot analysis, protein array analysis, or similar type analysis and the antibody specific for the defined Staphylococcus surrogate protein. In this example, to protect the human operators of the test, the synthetic defined Staphylococcus surrogate protein needs to incorporate critical characteristics of Staphylococcus proteins that are critical for the survival and growth of members of the Staphylococcus genus while avoiding organisms that can infect humans.

To design the synthetic defined Staphylococcus surrogate protein having SEQ ID NO: 4, a protein analysis was conducted comparing the amino acid sequences of the sup loci gene from multiple species of the Staphylococcus genus shown in Table 2 above. In this example, the Sequence IDs (found in Pubmed, www.ncbi.nlm.nih.gov/Pubmed/) for the suf I loci proteins, multiple Staphylococcus species, used for the comparative are shown in Table 8 below:

TABLE 8 (Staphylucoccus). Sequences used to determine regions of high homology in Suf I locus of multiple Staphylucoccus Species. Species Sequence ID Staphylucoccus aureus WP_000282432.1 Staphylucoccus epidermidis WP_023567454.1 Staphylucoccus saprophyticus OEK13316.1

The protein produced by the suf I loci is fundamental to survival and growth of a wide range of spores, bacteria and fungus. In species of the Staphylococcus genus, the protein product of the suf I loci is called cueO and is critical for many live stages including strongly contributing to cell survival and growth

To design the synthetic defined Staphylococcus surrogate protein, the specific amino acids from the proteins listed in Table 8 were aligned to determine amino acid sequence regions that are highly homologous in all evaluated Staphylococcus species as shown in FIG. 13. The protein encoded by the suf 1 loci includes three cupredoxin domains that are indicated at 240 for domain 1, 242 for domain 2, and 244 for domain 3. In the Staphylococcus genus, domain 2 indicated at 242 shows high homology between Staphylococcus species, so SEQ ID NO: 4 above was used to for the design of the synthetic defined Staphylococcus surrogate protein to be created for the Staphylococcus test and the corresponding peptide discussed above was used for a polyclonal antibody for use by Western Blot analysis.

Example 13: Developing Western Test to Qualify Ability to Destroy Staphylococcus Test Protein

One purpose of developing the defined Staphylococcus surrogate protein is to provide a method for rapidly determining the effectiveness of sterilization, deimmunization, and/or disinfection device, such as sterilization device, deimmunization device, or disinfection device and/or supplies. The method for rapidly determining effective sterilization, deimmunization, and/or disinfection includes multiple steps including at least: 1) preparing synthetic defined Staphylococcus surrogate protein test samples, 2) subjecting the defined Staphylococcus surrogate protein test samples to sterilization, deimmunization, and/or disinfection, and 3) using Western Blot or similar analysis to visualize the effects of sterilization, deimmunization, and/or disinfection of defined Staphylococcus surrogate protein test samples of the defined surrogate protein. Successful sterilization has occurred when all the defined Staphylococcus surrogate protein test samples are fragmented and as a result of the protein fragmentation, none remains to bind to the visualization antibodies indicating the defined Staphylococcus surrogate protein was destroyed. If sterilization, deimmunization, and/or disinfection was not successful, protein bands will be see on the Western Blot analysis.

Following the process more fully described for the Prion test, a similar process was followed to create the Staphylococcus sterilization, deimmunization, or disinfection test. First to create the sample for the test using the synthetic defined Staphylococcus surrogate protein, DNA encoding the amino acid SEQ ID NO: 4 above was synthesized and cloned into standard vectors both for E. coli and yeast expression. Using standard techniques, large quantities of the defined Staphylococcus surrogate protein were produced in E. coli or yeast and isolated by standard recombinant methods. Using a nickel column, a full-length defined Staphylococcus surrogate protein (171 amino acids long) was isolated. To create the samples having the synthetic defined Staphylococcus surrogate protein to qualify sterilization, deimmunization, and/or disinfection the samples were dried onto small filter papers, dried inside small tubes or a surface of an object subjected to sterilization, deimmunization, and/or disinfection e.g., using cycles of applying a solvent and microwave energy as disclosed in the '469 patent application.

After sterilization, deimmunization, and/or disinfection, the treated defined Staphylococcus surrogate protein samples were transferred to tubes, denatured and separated by size and transferred to nylon membrane before being permanently cross-linked to the membrane. The final steps include incubating the nylon membrane with a primary antibody that specifically binds to the Staphylococcus surrogate protein of interest. In the experiments discussed herein, the primary anti-suf I loci protein antibody was a rabbit polyclonal antibody that was raised against a synthetic peptide discussed above for SEQ ID NO: 4 residues. For added sensitivity, addition antibodies, both monoclonal and polyclonal, were raised against the other synthetic peptide(s). For the Western Blot analysis, a secondary antibody may be a HRP-labelled goat anti-rabbit to enable visualization of the protein fragments, both intact and fragmented. If the defined Staphylococcus surrogate proteins have completely fragmented no bands will be visualize on the Western blot. Very small fragments and amino acids will be too small to be retained on the gel. When successful sterilization, deimmunization, and/or disinfection occurred, the visualized Western blot has a dark ban in the untreated control sample, indicated at 250, FIG. 14, and a complete absence of any bands for defined Staphylococcus surrogate protein sample subjected to sterilization, deimmunization, or disinfection indicates successful sterilization, deimmunization, or disinfection, indicated at 252.

Example 14: Comparing Amino Acid Sequence of Multiple Members of the Pseudomonas Genus

It is important to qualify the ability of a sterilization device, a deimmunization device or disinfection device to destroy bacteria of any Pseudomonas species that may be contaminating medical equipment or supplies. In this example, a defined Pseudomonas surrogate protein quantity of the defined surrogate protein having a predetermined SEQ ID NO: 5 discussed above is subjected to sterilization, deimmunization, or disinfection to rapidly determine the effectiveness of the sterilization, deimmunization, or disinfection using Western Blot analysis, protein array analysis, or similar type analysis, and using an antibody specific for the defined Pseudomonas surrogate protein shown above. In this example, to protect the human operators of the test, the defined Pseudomonas surrogate protein needs to incorporate critical characteristics of Pseudomonas proteins that are critical for the survival and growth of members of the Pseudomonas genus while avoiding organisms that can infect humans.

To design the synthetic defined Pseudomonas surrogate protein having SEQ ID NO: 5, a protein analysis was conducted comparing the amino acid sequences of the suf loci gene from multiple species of the Pseudomonas genus shown in Table 2 above. In this example, the Sequence IDs (found in Pubmed, www.ncbi.nlm.nih.gov/Pubmed/) for the suf I loci Table 9 below:

TABLE 9 Pseudomonas. Sequences used to determine regions of high homology in suf 1 locus of multiple Pseudomonas Species. Species Sequence ID Pseudomonas aeruginosa WP_023096478.1 Pseudomonas fluorescens WP_003227851.1 Pseudomonas putida WP_019750583.1

The protein produced by the suf 1 loci is fundamental to survival and growth of a wide range of spores, bacteria and fungus. In species of the Pseudomonas genus, the protein product of the suf 1 loci is called cumA and is critical for many live stages including strongly contributing to the cell survival and growth

To design the defined Pseudomonas surrogate protein, the specific amino acids from the proteins listed in Table 9 were aligned to determine amino acid sequence regions that are highly homologous in all evaluated Pseudomonas species as shown in FIG. 15. The protein encoded by the suf 1 loci includes three cupredoxin domains indicated at 260 for domain 1, 262 for domain 2, and 264 for domain 3. In the Pseudomonas genus, domain 2, indicated at 262, shows high homology between Pseudomonas species so SEQ ID NO: 5 above was used to for the design of the synthetic surrogate protein to be created for the defined Pseudomonas surrogate protein test and the corresponding peptide shown above was used for a polyclonal antibody for use by Western Blot analysis.

Example 15: Developing Western Test to Qualify Ability to Destroy Pseudomonas Test Protein

One purpose of developing the defined Pseudomonas surrogate protein test is to create a method for rapidly determining the effectiveness of sterilization, deimmunization, and/or disinfection by a device, such as a sterilization device, a deimmunization device, or a disinfection device. The method for rapidly determining effective sterilization, deimmunization, and/or disinfection preferably includes multiple steps including at least: 1) preparing synthetic defined Pseudomonas surrogate protein test samples, 2) subjecting the synthetic Pseudomonas surrogate protein test samples to sterilization, deimmunization, and/or disinfection, and 3) using Western Blot or similar analysis to visualize the effects of sterilization, deimmunization, and/or disinfection of synthetic defined Pseudomonas surrogate test samples. Successful sterilization has occurred when all the defined Pseudomonas surrogate protein test samples are fragmented and as a result of the protein fragmentation, none remains to bind to the visualization antibodies indicating the defined Pseudomonas surrogate protein was destroyed. If sterilization, deimmunization, and/or disinfection was not successful, protein bands will be see on the Western Blot analysis.

Following the process more fully described for the Prion test, a similar process was followed to create the defined Pseudomonas sterilization, deimmunization and/or disinfection test. First, to create the sample for the test using the defined Pseudomonas surrogate protein, DNA encoding the amino acid SEQ ID NO: 5 defined above was synthesized and cloned into standard vectors both for E. coli and yeast expression. Using standard techniques, large quantities of the defined Pseudomonas surrogate protein were produced in E. coli or yeast and isolated by standard recombinant methods. Using a nickel column, a full-length synthetic defined Pseudomonas surrogate protein (171 amino acids long) was isolated. To create the samples having the synthetic defined surrogate protein to qualify sterilization, deimmunization, and/or disinfection of the samples were dried onto small filter papers, dried inside small tubes or a surface of an object subjected to sterilization, deimmunization, and/or disinfection, e.g., using cycles of applying a solvent and microwave energy as disclosed in the '469 patent application.

After sterilization, deimmunization, and/or disinfection, the treated defined Pseudomonas surrogate protein samples were transferred to tubes, denatured and separated by size and transferred to nylon membrane before being permanently cross-linked to the membrane. The final steps include incubating the nylon membrane with a primary antibody that specifically binds to the defined Pseudomonas surrogate protein. In the experiments discussed herein, the primary anti-suf 1 loci protein antibody was a rabbit polyclonal antibody that was raised against a synthetic peptide discussed above for SEQ ID NO: 5 residues. For added sensitivity, addition antibodies, both monoclonal and polyclonal, were raised against the other synthetic peptide(s). For the Western Blot Analysis, a secondary antibody may be a HRP-labelled goat anti-rabbit to enable visualization of the protein fragments, both intact and fragmented. If the synthetic defined Pseudomonas surrogate proteins have completely fragmented no bands will be visualize on the Western blot. Very small fragments and amino acids will be too small to be retained on the gel. When successful sterilization, deimmunization, or disinfection occurred, the visualized Western blot has a dark ban in the untreated control sample, e.g., indicated at 266, FIG. 16, and a complete absence of any bands for the defined Pseudomonas surrogate protein sample subjected to sterilization, deimmunization, or disinfection indicates successful sterilization, deimmunization, or disinfection, indicated at 268.

Example 16: Comparing Amino Acid Sequence of Multiple Members of the Trichophyton Genus

It is important to qualify the ability of a sterilization device, a deimmunization device, and/or a disinfection device to destroy bacteria of any Trichophyton species that may be contaminating medical equipment. In this example, a defined quantity of the defined Trichophyton surrogate protein having a predetermined SEQ ID NO: 6 discussed above is subjected to sterilization, deimmunization, or disinfection to rapidly determine the effectiveness of the sterilization, deimmunization, or disinfection using Western Blot analysis, protein array analysis, or similar type analysis and using the antibody specific for the defined Trichophyton surrogate protein. In this example, to protect the human operators of the test, the synthetic defined Trichophyton surrogate protein needs to incorporate critical characteristics of Trichophyton proteins that are critical for the survival and growth of members of the Trichophyton genus while avoiding organisms that can infect humans.

To design the synthetic defined Trichophyton surrogate protein having the SEQ ID NO: 6, a protein analysis was conducted comparing the amino acid sequences of the suf I loci gene from multiple species of the Trichophyton genus shown in Table 2 above. In this example, the Sequence IDs (found in Pubmed, www.ncbi.nhn.nih.gov/Pubmed/) for the suf I loci proteins, multiple Trichophyton species, used for the comparative are shown in Table 10 below:

TABLE 10 Trichophyton. Sequences used to determine regions of high homology in suf 1 locus of Trichophyton Species. Species Sequence ID Trichophyton rubrum XP_003236812.1 Trichophyton tonsurane EGD95875.1

The protein produced by the suf 1 loci is fundamental to survival and growth of a wide range of spores, bacteria and fungus. In species of the Trichophyton genus, the protein product of the suf 1 loci is called laccase and is critical for many live stages including strongly contributing to cell survival and growth

To design the synthetic defined Trichophyton surrogate protein, the specific amino acids from the proteins listed in Table 10 above were aligned to determine amino acid sequence regions that are highly homologous in all evaluated Trichophyton species as shown in FIG. 17. The protein encoded by the suf 1 loci includes three cupredoxin domains that are indicated at 270 for domain 1, 272 for domain 2, and 274 for domain 3. In the Trichophyton genus, domain 2, indicated at 272, shows high homology between Trichophyton species so SEQ ID NO: 6 above was used to for the design of the synthetic defined Trichophyton surrogate protein to be created for the Trichophyton test and the corresponding peptide discussed above was used for a polyclonal antibody for use by Western Blot analysis.

Example 17: Developing Western Test to Qualify Ability to Destroy Trichophyton Test Protein

One purpose of developing the defined Trichophyton surrogate protein is to provide a method for rapidly determining the effectiveness of sterilization, deimmunization, and/or disinfection by a device, such as sterilization device, a deimmunization device, or a disinfection device. The method for rapidly determining effective sterilization, deimmunization, or disinfection preferably includes multiple steps including at least: 1) preparing synthetic defined Trichophyton surrogate protein test samples, 2) subjecting the defined Trichophyton surrogate protein test samples to sterilization, deimmunization, or disinfection, and 3) using Western Blot or similar analysis to visualize the effects of sterilization, deimmunization, or disinfection of defined Trichophyton surrogate protein test samples. Successful sterilization, deimmunization, or disinfection has occurred when all the defined Trichophyton surrogate protein test samples are fragmented and as a result of the protein fragmentation, none remains to bind to the visualization antibodies indicating the defined Trichophyton surrogate protein was destroyed. If sterilization, deimmunization and/or disinfection was not successful, protein bands will be see on the Western Blot analysis.

Following the process more fully described for the Prion test, a similar process was followed to create the Trichophyton sterilization, deimmunization and/or disinfection test. First, to create the sample for the test using the synthetic defined Trichophyton surrogate protein, DNA encoding the amino acid SEQ ID NO: 7 above was synthesized and cloned into standard vectors both for E. coli and yeast expression. Using standard techniques, large quantities of defined Trichophyton surrogate protein were produced in E. coli or yeast and isolated by standard recombinant methods. Using a nickel column, a full-length synthetic defined Trichophyton surrogate protein (171 amino acids long) was isolated. To create the samples having the synthetic defined Trichophyton surrogate protein to qualify sterilization, deimmunization, or disinfection, the defined Trichophyton surrogate protein samples were dried onto small filter papers, dried inside small tubes or a surface of an object subjected to sterilization, deimmunization and/or disinfection, e.g., using cycles of applying a solvent and microwave energy as disclosed in the '469 patent application.

After sterilization, deimmunization, or disinfection, the treated Trichophyton samples were transferred to tubes, denatured and separated by size and transferred to nylon membrane before being permanently cross-linked to the membrane. The final steps include incubating the nylon membrane with a primary antibody that specifically binds to the protein of interest. In the experiments discussed herein, the primary anti-suf 1 loci protein antibody was a rabbit polyclonal antibody that was raised against a synthetic peptide discussed above for SEQ ID NO: 6 residues. For added sensitivity, addition antibodies, both monoclonal and polyclonal, were raised against the other synthetic peptide(s). For the Western Blot analysis, a secondary antibody may be a HRP-labelled goat anti-rabbit to enable visualization of the protein fragments, both intact and fragmented. If the proteins have completely fragmented no bands will be visualize on the Western blot. Very small fragments and amino acids will be too small to be retained, on the gel. When successful sterilization, deimmunization, or disinfection has occurred, the visualized Western blot has a dark ban in the untreated control sample, e.g., indicated at 276, FIG. 18, and a complete absence of any bands for the defined Trichophyton surrogate protein sample subjected to sterilization, deimmunization, or disinfection indicates successful sterilization, deimmunization, or disinfection, indicated at 278.

Example 18: Comparing Amino Acid Sequence of Multiple Members of the Candida Genus

It is important to qualify the ability of a sterilization device, a deimmunization device, or disinfection device, to destroy bacteria of any Candida species that may be contaminating medical equipment. In this example, a defined quantity of the defined Candida surrogate protein having a predetermined SEQ ID NO: 7 discussed above is subjected to sterilization, deimmunization, or disinfection to rapidly determine the effectiveness of the sterilization, deimmunization, or disinfection using Western Blot analysis, protein array analysis, or similar type analysis and the antibody specific for the defined Candida surrogate protein. In this example, to protect the human operators of the test, the defined Candida surrogate protein needs to incorporate critical characteristics of Candida proteins that are critical for the survival and growth of members of the Candida genus while avoiding organisms that can infect humans.

To design the synthetic defined Candida surrogate protein having the SEQ ID NO: 7, a protein analysis was conducted comparing the amino acid sequences of the suf 1 loci gene from multiple species of the Candida genus shown in Table 2 above. In this example, the Sequence IDs (found in Pubmed, www.ncbi.nlm.nih.gov/Pubmed/) for the suf 1 loci proteins, multiple Candida species, used for the comparative are shown in Table 11 below:

TABLE 11 (Candida). Sequences used to determine regions of high homology in Suf I locus of Candida Species. Species Sequence ID Candida albicans KHC71512.1 Candida dubliniensis XP_002420841.1 Candida tropicalis XP_002548698.1 Candida auris XP_018169615.1

The protein produced by the suf I loci is fundamental to survival and growth of a wide range of spores, bacteria and fungus. In species of the Candida genus, the protein product of the suf I loci is called laccase and is critical for many live stages including strongly contributing to cell survival and growth

To design the synthetic defined Candida surrogate protein, the specific amino acids from the proteins listed in Table 11 were aligned to determine amino acid sequence regions that are highly homologous in all evaluated Candida species as shown in FIG. 19. The protein encoded by the suf 1 loci includes three cupredoxin domains, indicated at 280 for domain 1, 282 for domain 2, and 284 for domain 3. In the Candida genus, domain 2, indicated at 284, shows high homology between Candida species so SEQ ID NO: 7 above was used to for the design of the synthetic defined Candida surrogate protein to be created for the Candida test and the corresponding peptide discussed above was used for a polyclonal antibody for use by Western Blot analysis.

Example 19: Developing Western Test to Qualify Ability to Destroy Candida Test Protein

One purpose of developing the defined Candida surrogate protein test is to provide a method for rapidly determining the effectiveness of sterilization, deimmunization, and/or disinfection by a device, such as a sterilization device, a deimmunization device, or a disinfection device. The method for rapidly determining effective sterilization, deimmunization, and/or disinfection includes multiple steps preferably including at least: 1) preparing synthetic defined Candida surrogate protein test samples, 2) subjecting the defined Candida surrogate protein test samples to sterilization, deimmunization, or disinfection, and 3) using Western Blot or similar analysis to visualize the effects of sterilization, deimmunization, or disinfection of defined Candida surrogate protein test samples. Successful sterilization, deimmunization, or disinfection has occurred when all the defined Candida surrogate protein test samples are fragmented and as a result of the protein fragmentation, none remains to bind to the visualization antibodies indicating the defined Candida surrogate protein was destroyed. If sterilization, deimmunization, or disinfection was not successful, protein bands will be see on the Western Blot analysis.

Following the process more fully described for the Prion test, a similar process was followed to create the defined Candida surrogate protein sterilization, deimmunization and/or disinfection test. First, to create the sample for the synthetic defined Candida surrogate protein test using the defined Candida surrogate protein, DNA encoding the amino acid SEQ ID NO: 7 was synthesized and cloned into standard vectors both for E. coli and yeast expression. Using standard techniques, large quantities of protein were produced in E. coli or yeast and isolated by standard recombinant methods. Using a nickel column, a full-length synthetic defined Candida surrogate protein (171 amino acids long) was isolated. To create the samples having the synthetic defined Candida surrogate protein to qualify sterilization, deimmunization, or disinfection, the samples having the defined Candida surrogate protein were dried onto small filter papers, dried inside small tubes or a surface of an object subjected to sterilization, deimmunization, and/or disinfection, e.g., using cycles of applying a solvent and microwave energy as discussed in the '469 patent application.

After sterilization, deimmunization, or disinfection, the treated defined Candida surrogate protein samples were transferred to tubes, denatured and separated by size and transferred to nylon membrane before being permanently cross-linked to the membrane. The final steps include incubating the nylon membrane with a primary antibody that specifically binds to the defined Candida surrogate protein. In the experiments discussed herein, the primary anti-suf 1 loci protein antibody was a rabbit polyclonal antibody that was raised against a synthetic peptide discussed above for SEQ ID NO: 7 residues. For added sensitivity, addition antibodies, both monoclonal and polyclonal, were raised against the other synthetic peptide(s). For the Western Blot analysis, a secondary antibody may be a HRP-labelled goat anti-rabbit to enable visualization of the protein fragments, both intact and fragmented. If the proteins have completely fragmented no bands will be visualize on the Western blot. Very small fragments and amino acids will be too small to be retained on the gel. When successful sterilization, deimmunization, or disinfection has occurred, the visualized Western blot has a dark ban in the untreated control sample, indicated at 286, FIG. 20, and a complete absence of any bands for the defined Candida surrogate protein sample subjected to sterilization, deimmunization, or disinfection indicates successful sterilization, deimmunization, or disinfection, indicated at 290.

Example 20: Immobilizing Proteins onto a Solid Surface

Many processes and solid substrates are well known in the art for immobilizing proteins onto a solid surface. In this example, glass slides were obtained having round wells created by printing the glass with highly water-repellent mark, e.g., as shown by multi-well glass slides 130, 134, FIG. 2, or multi-well glass slide 152, FIG. 3. In this example, the glass slides were washed with acetone and milli-Q water before soaking overnight in 1 M NaOH (room temperature). To create amino silane-treated slides, washed slides using milli-Q water and 99.5% ethanol, were treated with 3-aminopropyltriethoxysilane for 2 hours at room temperature, washed with milli-Q water, and baked for 2 hr. at 100° C. The multi-well slides were soaked in 1% (v/v) glutaraldehyde overnight at 37° C. to produce glutaraldehyde-treated slides. The slides were then incubated overnight at 37° C. in chitosan (0.05% (w/v)) dissolved in 0.1 M acetic acid buffer (pH 5.0) supplemented with 0.25 mM sodium azide. The treated slides were rinsed twice with 0.1 M acetic acid buffer (pH 5) and then three times with water before being soaked in 1% (v/v) glutaraldehyde overnight at 37° C. The slides were incubated overnight at 37° C. in a 0.05% (w/v) solution of N-(5-Amino-1-carboxy pentyl) iminodiacetic acid (AB-NTA) in 0.1 M HEPES buffer (pH 8.0), then rinsed 3 times with milli-Q water. The slides were then soaked in blocking solution (1% (v/v) glycine) for 1 h at 37° C., then rinsed 3 times with milli-Q water, 3 times with 0.5 M NiCl2, and 3 times with milli-Q water to produce Ni-NTA immobilized slides ready for protein immobilization.

In this example, the defined Clostridium surrogate protein having SEQ ID NO: 1 was diluted in TG buffer (50 mM Tris-HCl (pH 8.0), 10% (v/v) glycerol) to 200 μg/ml. Different quantities of the defined Clostridium surrogate protein, e.g., 200 ng, 100 ng, 50 ng, 25 ng, 12.5 ng, 6.25 ng, 3.125 ng, 1.562 ng, 0.781 ng and 0 ng, were spotted in individual wells, e.g., the wells exemplarily indicated at 132 and 136, FIG. 2, and incubated for 60 min in a moist, dark chamber and finished by washing with TG buffer. After subjecting the slides 130 and 134 to sterilization, deimmunization, or disinfection using cycles of a solvent and electromagnetic radiation, e.g., microwaves as disclosed in the '469 patent application, slides 130 and 134 were incubated with anti-Clostridium antibodies discussed above raised against the peptide selected from SEQ ID NO: 1. To visualize the amount of the defined Clostridium surrogate protein remaining after sterilization, deimmunization, or disinfection, the slides were then treated with anti-Ig antibody labeled with the fluorescence dye fluorescence isothiocynate (FITC). A matched slide that was not sterilized in this example, slide 130, was used as a control for the protein array analysis. Using a fluorescence microscope with camera, the loss of protein can be visualized that can be detected with the specific anti-Clostridium antibodies. With additional fluorescence detection equipment, such as automated readers, increasing sensitivity and titration of detection can be added. An example of successful sterilization, deimmunization and/or disinfection is indicated at 140, for slide 134, FIG. 2, when compared against control slide 130 which visibly shows color, indicated by the shading in wells 132. Confirmatory tests were conducted by including samples of intact C. sporogenes using cycles of a solvent and electromagnetic energy or microwaves, e.g., as disclosed in the '469 patent application. After treatment, the intact bacteria were processed following industry standard protocols. Similar methods may be used for any of Examples 6 to 18 above.

Example 21: Comparing Amino Acid Sequence of α-Gliadin from Appropriate Human Consumed Grains

To develop a test to qualify the ability of a sterilization device, deimmunization, or disinfection to destroy medically important immunogenic proteins, such as α-gliadin, that may be contaminating medical equipment, the following experiments were conducted. In this example, to rapidly detect effective deimmunization, a defined quality of an isolated protein needs to be deimmunized with a deimmunization device, e.g., using cycles of a combination of a solvent and electromagnetic microwaves radiation, e.g., microwaves, as disclosed in the '469 patent application and then evaluated by Western Blot analysis using an antibody specific for the protein. To design a candidate protein to serve as the representative defined surrogate α-gliadin protein having a predetermined sequence, the translated sequences of representative α-gliadin genes from many commonly consumed human grains were aligned. See Table 13 and Table 14 below. Gliadin protein is the immunogenic component of gluten and must be avoided by Celiac patients. FIG. 21 shows the amino acid numbering aligned with an example of Bread wheat α-Gliadin. The underline region, indicated at 400, is the polypeptide that acts as common immunogen in a majority of Celiac Patients. Regions at 402, 404 indicate protein region used to design test immunogen reagent.

TABLE 13 Sequence ID of α-Gliadin Proteins or Prolamins in Common Grains Used to Design Recombinant Protein Sequence. Sequence ID Common Name Species Name Number w/Link Bread Wheat Triticum aestivum pir||A27319 Common Wheat Triticum sphaerococcum ABQ45316.1 Durum wheat/Pasta Triticum turgidum subsp. ADA83698.1 Wheat durum Farro/Emmer Wheat Triticum dicoccon AKC91191.1 Macha Wheat Triticum macha AKC91223.1 Rye Secale cereale AFK32718.1 Spelt/Dinkel Wheat Triticum spelta APU92351.1 Red Wild Einkor Triticum urartu AKC91171.1 Precursor αGliadin Triticum aestivum Q41545 Bateman et al 2004

TABLE 14 Additional α-Gliadin Protein Sequences that could be used to design Recombinant Protein. Sequence Species Common ID Species Common Name Sequence ID Triticum Bread pir||A27319 Triticum Durum wheat, pasta ADA83698.1 aestivum Wheat P04726.1 turgidum wheat or macaroni ADA83690.1 subsp. wheat durum AED99851.1 Triticum Emmer wheat or Farro AKC91191.1 dicoccon SCW25751.1 Triticum red wild einkor AKC91171.1 urartu AHY37812.1 Triticum Macha wheat AKC91223.1 macha AHY37818.1 Secale Rye AFK32718.1 cereale AFX69612.1 ABQ52118.1 Aegilops Tausch's goatgrass AFX69602.1 AFX69616.1 tauschii XP_020186089.1 AFX69586.1 AKC91337.1 Triticum Common ABQ45316.1 ABQ52112.1 sphaerococcum wheat Triticum spelta Spelt or APU92351.1 Aegilops Sharon goatgrass AMS25611.1 dinkel APU92675.1 sharonensis AMS25610.1 wheat APU92554.1 AMS25614.1 APU92300.1 Aegilops Goatgrass AKC91312.1 searsii APU92425.1 AKC91311.1 APU92357.1 Aegilops Goatgrass AHN85624.1 speltoides APU92415.1 Aegilops Goatgrass AHN85626.1 speltoides APU92583.1 Aegilops Goatgrass AEV55370.1 uniaristata APU92336.1 Thinopyrum Wild Thinopyrum ADP94197.1 APU92334.1 bessarabicum grasses In this example, the defined α-Gliadin surrogate protein has the following predetermined sequence:

For α-Gliadin:

(SEQ ID NO: 8)         10          20          30          40          50 MKTVRVPVPQ  PQPQNPSQPQ  PQRQVPLVQQ  QQFPGQQQQF  PPQQPYPQPQ PFPSQQPYLQ  LQPFPQPQPF  PPQLPYHHHH  HH The peptide used for the development of monoclonal or polyclonal antibody used by Western Blot analysis for the above sequence is:

(SEQ ID NO: 24) FPPQQPYPQPQPFPSQQPYLQLQPFPQPQ A fragment of this peptide (KLQPFPQPELPYPQPQ (SEQ ID NO: 25)) in form is the medically important immunogen is CD.

If the defined α-Gliadin surrogate proteins have completely fragmented, no bands will be visualized on the Western Blot. Very small fragments in amino acid would be too small to be retained on the gel. When successful deimmunization, in this example, has occurred, the visualized Western Blot has a dark band in the untreated control sample, e.g., indicated at 420, FIG. 22, and a complete absence of any bands for the defined α-Gliadin surrogate protein sample subject to deimmunization indicates successful deimmunization, e.g., indicated at 422.

Confirmatory tests were conducted by including samples of intact wheat flour using a combination of cycles of a solvent and microwaves, e.g., as disclosed in the '469 patent application. After treatment, the intact wheat flour samples were processed following industry standard protocols to test for the presence of gluten in food stuffs.

Although specific features of the invention are shown in some drawings and not in others, this is for convenience only as each feature may be combined with any or all of the other features in accordance with the invention. The words “including”, “comprising”, “having”, and “with” as used herein are to be interpreted broadly and comprehensively and are not limited to any physical interconnection. Moreover, any embodiments disclosed in the subject application are not to be taken as the only possible embodiments. Other embodiments will occur to those skilled in the art and are within the following claims.

In addition, any amendment presented during the prosecution of the patent application for this patent is not a disclaimer of any claim elementpresented in the application as filed: those skilled in the art cannot reasonably be expected to draft a claim that would literally encompass all possible equivalents, many equivalents will be unforeseeable at the time of the amendment and are beyond a fair interpretation of what is to be surrendered (if anything), the rationale underlying the amendment may bear no more than a tangential relation to many equivalents, and/or there are many other reasons the applicant cannot be expected to describe certain insubstantial substitutes for any claim element amended. 

What is claimed is:
 1. A method for rapidly determining effective sterilization, deimmunization, and/or disinfection of equipment and/or supplies by a device, the method comprising: providing a defined surrogate protein having a predetermined sequence representative of an infectious agent potentially contaminating the equipment and/or the supplies to be sterilized, deimmunized, and/or disinfected by the device; subjecting the defined surrogate protein having the predetermined sequence to sterilization, deimmunization, or disinfection; and rapidly determining the effectiveness of the sterilization, deimmunization, and/or disinfection by determining if the defined surrogate protein having the predetermined sequence has been destroyed.
 2. The method of claim 1 in which the defined surrogate protein includes proteins critical for stability, growth and/or infectious capacity of infectious agents.
 3. The method of claim 1 in which the defined surrogate protein includes a protein critical for stability, growth and/or infectious capacity of surrogate organisms of infectious agents.
 4. The method of claim 2 in which the infectious agent includes one or more of: an infectious protein, an infectious spore forming bacteria, an infectious vegetative bacteria, an infections fungus, and an infectious virus.
 5. The method of claim 1 in which the defined surrogate protein includes pathogenic proteins, proteins critical for the growth of infectious agents, and immunogenic proteins.
 6. The method of claim 1 in which the predetermined sequence is defined by the sequence: (SEQ ID NO: 1)         10          20          30          40          50 MYNYTSAKYE  VPIAIQDRSF  NEDGSLNFPS  EGDNPTIHPY  WQPEFFGDTI MVNGRVWPNM  NVDMTRYRFR  LLNGSNARFY  NLKFSNGMQF  WQIGTDGGYL NKPVPLTSLL  ISPGERADIL  VDFTEIPAGT  RIILNNDANA  PYPTGDAPDK DTTGQIMQFT  VQHNDHHHHH  H


7. The method of claim 6 in which the defined surrogate protein is at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence.
 8. The method of claim 1 in which the predetermined sequence is defined by the sequence: (SEQ ID NO: 2)         10          20          30          40          50 MTLEKTYYEV  TMEECTHQLH  RDLPPTRLWG  YNGLFPGPTI  EVKRNENVYV KWMNNLPSTH  FLPIDHTIHH  SDSQHEEPEV  KTVVHLHGGV  TPDDSDGYPE AWFSKDFEQT  GPYFKREVYH  YPNQQRGAIL  WYHDHAMALT  RLNVYAGLVG AYIIHDPKEK  RLKHHHHHH


9. The method of claim 8 in which the defined surrogate protein is at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence.
 10. The method of claim 1 in which the predetermined sequence is defined by the sequence: (SEQ ID NO: 3)         10          20          30          40          50 MTGMPEGEGV  DSNLLGGDGG  DIAYPYYLIN  GRIPVAATSF  KAKPGQRIRI RIINSAADTA  FRIALAGHSM  TVTHTDGYPV  IPTEVDALLI  GMAERYDVMV TAAGGVFPLV  ALAEGKNALA  RALLSTGAGS  PPDHHHHHH


11. The method of claim 10 in which the defined surrogate protein is at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence.
 12. The method of claim 1 in which the predetermined sequence is defined by the sequence: (SEQ ID NO: 4)         10          20          30          40          50 MTGYKNYTLK  AQKGKTEFYK  NNFSNTLGYN  GNLLGPTLKL  KKGDKVKIKL INNLDENTTF  HWHGLEVNGK  VDGGPSQVIK  PGKEKTIKFE  VNQDSATLWY HPHPSPNTAK  QVYNGLSGLL  YIEDSKKNHH  HHHH


13. The method of claim 12 in which the defined surrogate protein is at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence.
 14. The method of claim 1 in which the predetermined sequence is defined by the sequence: (SEQ ID NO: 5)         10          20          30          40          50 MTGFRHEKVL  CLKTWHVDEQ  GAFTPFSVPR  QAAREGTRGR  YSTINGKHVP TIDLPAGQIV  RVRLLNVDNT  VTYRLNPNGE  ARIYAVDGHP  VEPRGFEGQY WIGPGMRLEL  ALKVPEAGTE  LSLRDGPVRL  ATIRSVAHHH  HHH


15. The method of claim 14 in which the defined surrogate protein is at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence.
 16. The method of claim 1 in which the predetermined sequence is defined by the sequence: (SEQ ID NO: 6)         10          20          30          40          50 MTITLEWSVT  TGYRRLDGVK  KRVYLINGLF  PGPTIEARSG  DSLQVQVTNN IQDEGLVIHW  HGLHMRGANH  MDGVTGVTQC  PIVPGDSMLY  NFTISQSQSG TFWYHAHSAL  QRAEGLYGGF  VVHKPSTHHH  HHH


17. The method of claim 16 in which the defined surrogate protein is at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence.
 18. The method of claim 1 in which the predetermined sequence is defined by the sequence: (SEQ ID NO: 7)         10          20          30          40          50 MTAETHTWYF  KTSWVDANPD  GVFPRKMIGF  NDSWPLPTLR  VKKGDTVNLY LINGFDDRNT  SLHFHGLFQH  GTNQMDGPEM  VTQCPIPPGE  TFLYNFTVDD QVGSYWYHSH  TSGQYGDGMR  GVFIIEDHHH  HHH


19. The method of claim 18 in which the defined surrogate protein is at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence.
 20. The method of claim 1 in which the predetermined sequence is defined by the sequence: (SEQ ID NO: 8)         10          20          30          40          50 MKTVRVPVPQ  PQPQNPSQPQ  PQRQVPLVQQ  QQFPGQQQQF  PPQQPYPQPQ PFPSQQPYLQ  LQPFPQPQPF  PPQLPYHHHH  HH


21. The method of claim 20 in which the defined surrogate protein is at least 95% homologous the predetermined sequence or substantial fragment of the predetermined sequence.
 22. The method of claim 1 in which the rapidly determining including a sensitive protein analysis procedure.
 23. The method of claim 22 in which the sensitive protein analysis procedure includes one or more of: a Western Blot analysis, a protein assay analysis, a magnetic separation analysis, a peptide analysis, a mass spectrometry analysis, and a gas chromatography analysis.
 24. The method of claim 22 in which the sensitive protein analysis procedure includes fluorescence analysis of proteins covalently crosslinked on a solid surface.
 24. The method of claim 22 in which the sensitive protein analysis procedure includes fluorescence analysis of proteins covalently crosslinked on magnetic beads.
 25. The method of claim 1 in which the defined surrogate protein having the predetermined sequence is disposed on a surface.
 26. The method of claim 1 in which the defined surrogate protein having the predetermined sequence is disposed on a test strip.
 27. The method of claim 1 in which the defined surrogate protein having the predetermined sequence is disposed in or on a vessel.
 29. The method of claim 1 in which the surrogate protein having the predetermined sequence is disposed on a tube.
 30. The method of claim 30 in which the surrogate protein having the predetermined sequence is disposed on a holder.
 31. The method of claim 1 in which the holder is disposed to receive a flow of a sterilization agent, a deimmunization agent or a disinfection agent. 